Solutions Manual Microelectronic Circuit

Solutions Manual - Microelectronic Circuit Design - 4th Ed By Richard C. Jaeger, Travis N. Blalock - McGraw-Hill (2010) NOTE: these answers are for the International Edition (?) But they’re still very similar to the original (sometimes a, b, c, d answers will be switched around, and some numbers may be a little off. As a general rule, subtract 3 from the answer you are looking for and that should be the real one) Special thanks to Moser from NIU for the main files February 1, 2012 Go to this website for book updates / corrections by the publisher: http://www.jaegerblalock.com/ 1.1 Answering machine Alarm clock Automatic door Automatic lights ATM Automobile: Engine controller Temperature control ABS Electronic dash Navigation system Automotive tune-up equipment Baggage scanner Bar code scanner Battery charger Cable/DSL Modems and routers Calculator Camcorder Carbon monoxide detector Cash register CD and DVD players Ceiling fan (remote) Cellular phones Coffee maker Compass Copy machine Cordless phone Depth finder Digital Camera Digital watch Digital voice recorder Digital scale Digital thermometer Electronic dart board Electric guitar Electronic door bell Electronic gas pump Elevator Exercise machine Fax machine Fish finder Garage door opener GPS Hearing aid Invisible dog fences Laser pointer LCD projector Light dimmer Keyboard synthesizer Keyless entry system Laboratory instruments Metal detector Microwave oven Model airplanes MP3 player Musical greeting cards Musical tuner Pagers Personal computer Personal planner/organizer (PDA) Radar detector Broadcast Radio (AM/FM/Shortwave) Razor Satellite radio receiver Security systems Sewing machine Smoke detector Sprinkler system Stereo system Amplifier CD/DVD player Receiver Tape player Stud sensor Talking toys Telephone Telescope controller Thermostats Toy robots Traffic light controller TV receiver & remote control Variable speed appliances Blender Drill Mixer Food processor Fan Vending machines Video game controllers Wireless headphones & speakers Wireless thermometer Workstations Electromechanical Appliances* Air conditioning and heating systems Clothes washer and dryer Dish washer Electrical timer Iron, vacuum cleaner, toaster Oven, refrigerator, stove, etc. *These appliances are historically based only upon on-off (bang-bang) control. However, many of the high end versions of these appliances have now added sophisticated electronic control. 1-1 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.2 B = 19.97 x 100.1997(2020−1960) = 14.5 x 1012 = 14.5 Tb/chip 1.3 (a) 0.1977(Y2 −1960) B2 19.97x10 0.1977(Y2 −Y1 ) 0.1977(Y2 −Y1 ) = = 10 so 2 = 10 0.1977(Y1 −1960) B1 19.97x10 Y2 − Y1 = (b) log2 = 1.52 years 0.1977 Y2 − Y1 = log10 = 5.06 years 0.1977 1.4 0.1548(2020−1970) N = 1610x10 1.5 = 8.85 x 1010 transistors/μP (2 ) N 2 1610x10 0.1548(Y2 −Y1 ) = = 10 0.1548(Y1 −1970) N1 1610x10 log2 (a) Y2 − Y1 = = 1.95 years 0.1548 log10 (b) Y2 − Y1 = = 6.46 years 0.1548 0.1548 Y −1970 1.6 −0.05806(2020−1970) F = 8.00x10 μm = 10 nm . No, this distance corresponds to the diameter of only a few atoms. Also, the wavelength of the radiation needed to expose such patterns during fabrication is represents a serious problem. 1.7 From Fig. 1.4, there are approximately 600 million transistors on a complex Pentium IV microprocessor in 2004. From Prob. 1.4, the number of transistors/μP will be 8.85 x 1010. in 2020. Thus there will be the equivalent of 8.85x1010/6x108 = 148 Pentium IV processors. 1-2 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.8 ( ) P = 75x106 tubes (1.5W tube)= 113 MW! I= 1.13 x 108W = 511 kA! 220V D, D, A, A, D, A, A, D, A, D, A 1.9 1.10 10.24V 10.24V 10.24V = = 2.500 mV VMSB = = 5.120V 12 2 2 bits 4096bits 1001001001102 = 211 + 28 + 25 + 22 + 2 = 234210 VO = 2342(2.500mV )= 5.855 V VLSB = 1.11 VLSB = 5V 5V mV = = 19.53 bit 2 bits 256bits 8 2.77V = 142 LSB mV 19.53 bit and 14210 = (128 + 8 + 4 + 2) = 100011102 10 1.12 VLSB = 2.5V 2.5V mV = = 2.44 bit 2 bits 1024 bits 10 ( 01011011012 = 28 + 26 + 25 + 23 + 22 + 20 ) 10 ⎛ 2.5V ⎞ VO = 365 ⎜ ⎟ = 0.891 V ⎝ 1024 ⎠ = 36510 1.13 ( ) 10V mV 6.83V 14 = 0.6104 and 2 bits = 11191 bits 14 bit 10V 2 bits 1119110 = (8192 + 2048 + 512 + 256 + 128 + 32 + 16 + 4 + 2 + 1) 10 VLSB = 1119110 = 101011101101112 1.14 A 4 digit readout ranges from 0000 to 9999 and has a resolution of 1 part in 10,000. The number of bits must satisfy 2B ≥ 10,000 where B is the number of bits. Here B = 14 bits. 1.15 5.12V 5.12V mV V = = 1.25 and VO = (1011101110112 )VLSB ± LSB 12 bit 2 2 bits 4096 bits 11 9 8 7 5 4 3 VO = 2 + 2 + 2 + 2 + 2 + 2 + 2 + 2 + 1 1.25mV ± 0.0625V VLSB = ( ) 10 VO = 3.754 ± 0.000625 or 3.753V ≤ VO ≤ 3.755V 1-3 6/9/06 1.16 IB = dc component = 0.002 A, ib = signal component = 0.002 cos (1000t) A 1.17 VGS = 4 V, vgs = 0.5u(t-1) + 0.2 cos 2000 t Volts 1.18 vCE = [5 + 2 cos (5000t)] V 1.19 vDS = [5 + 2 sin (2500t) + 4 sin (1000t)] V 1.20 V = 10 V, R1 = 22 kΩ, R2= 47 kΩ and R3 = 180 kΩ. + V 1 R I2 1 R2 V I + V 3 R 2 3 - V1 = 10V 22kΩ ( ) 22kΩ + 47kΩ 180kΩ = 10V 22kΩ = 3.71 V 22kΩ + 37.3kΩ 37.3kΩ = 6.29 V Checking : 6.29 + 3.71 = 10.0 V 22kΩ + 37.3kΩ ⎛ ⎞ 180kΩ 180kΩ 10V I2 = I1 =⎜ = 134 μA ⎟ 47kΩ + 180kΩ ⎝ 22kΩ + 37.3kΩ ⎠ 47kΩ + 180kΩ ⎛ ⎞ 47kΩ 47kΩ 10V I3 = I1 =⎜ = 34.9 μA ⎟ 47kΩ + 180kΩ ⎝ 22kΩ + 37.3kΩ ⎠ 47kΩ + 180kΩ V2 = 10V Checking : I1 = 10V = 169μA and I1 = I2 + I3 22kΩ + 37.3kΩ 1-4 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.21 V = 18 V, R1 = 56 kΩ, R2= 33 kΩ and R3 = 11 kΩ. V + 1 R I R V I3 + 2 1 V 2 R 2 3 - V1 = 18V 56kΩ ( ) 56kΩ + 33kΩ 11kΩ = 15.7 V V2 = 18V 33kΩ 11kΩ ( ) 56kΩ + 33kΩ 11kΩ = 2.31 V Checking :V1 + V2 = 15.7 + 2.31 = 18.0 V which is correct. I1 = 18V ( ) 56kΩ + 33kΩ 11kΩ I3 = I1 = 280 μA I2 = I1 11kΩ 11kΩ = (280 μA) = 70.0 μA 33kΩ + 11kΩ 33kΩ + 11kΩ 33kΩ 33kΩ = (280 μA) = 210 μA 33kΩ + 11kΩ 33kΩ + 11kΩ 1.22 I1 = 5mA (5.6kΩ + 3.6kΩ) = 3.97 mA (5.6kΩ + 3.6kΩ)+ 2.4kΩ ( Checking : I2 + I3 = 280 μA I2 = 5mA 2.4kΩ = 1.03 mA 9.2kΩ + 2.4kΩ = 3.72V )5.6kΩ3.6kΩ + 3.6kΩ V3 = 5mA 2.4kΩ 9.2kΩ Checking : I1 + I2 = 5.00 mA and I2 R2 = 1.03mA(3.6kΩ)= 3.71 V 1.23 150kΩ 150kΩ = 125 μA I3 = 250μA = 125 μA 150kΩ + 150kΩ 150kΩ + 150kΩ 82kΩ V3 = 250μA 150kΩ 150kΩ = 10.3V 68kΩ + 82kΩ Checking : I1 + I2 = 250 μA and I2 R2 = 125μA(82kΩ)= 10.3 V I2 = 250μA ( ) 1-5 6/9/06 1.24 + R v v 1 s + g v v m th - Summing currents at the output node yields: v + .002v = 0 so v = 0 and v th = vs − v = vs 5x10 4 + v - R 1 ix g v m vx Summing currents at the output node : v − 0.002v = 0 but v = −vx 5x10 4 vx v 1 ix = + 0.002vx = 0 Rth = x = = 495 Ω 4 1 ix 5x10 + gm R1 ix = − Thévenin equivalent circuit: 495 Ω v s 1-6 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.25 The Thévenin equivalent resistance is found using the same approach as Problem 1.24, and ⎛ 1 ⎞−1 Rth = ⎜ + .025⎟ = 39.6 Ω ⎝ 4kΩ ⎠ + v R 1 - vs g v m in The short circuit current is : v in = + 0.025v and v = vs 4kΩ v i n = s + 0.025vs = 0.0253vs 4kΩ Norton equivalent circuit: 0.0253v s 39.6 Ω 1-7 6/9/06 1.26 (a) + βi R vs R2 1 v th i Vth = Voc = −β i R2 - i =− but vs R1 and Vth = β vs R2 39kΩ = 120 vs = 46.8 vs R1 100kΩ ix βi R R2 1 v Rth x i Rth = vx ; ix ix = vx + βi R2 but i = 0 since VR 1 = 0. Rth = R2 = 39 kΩ. Thévenin equivalent circuit: 39 k Ω 58.5v s (b) + βi i s R R2 1 i v th - ⎛ i ⎞ Vth = Voc = −β i R2 where i + bi + is = 0 and Vth = −β ⎜ − s ⎟ R2 = 38700 is ⎝ β + 1⎠ 1-8 ©R. C. Jaeger & T. N. Blalock 6/9/06 βi R R2 1 Rth v x i Rth = vx ; ix ix = vx + βi but R2 i + βi = 0 so i = 0 and Rth = R2 = 39 kΩ Thévenin equivalent circuit: 39 k Ω 38700i s 1.27 βi R vs R2 1 in i in = −β i but i = − vs R1 and in = β R1 vs = From problem 1.26(a), Rth = R2 = 56 kΩ. 0.00133v s 100 vs = 1.33 x 10−3 vs 75kΩ Norton equivalent circuit: 56 k Ω 1-9 6/9/06 1.28 is v βi R s R2 1 i is = vs v v β +1 − β i = s + β s = vs R1 R1 R1 R1 R= vs R 100kΩ = 1 = = 1.24 Ω is β + 1 81 1.29 The open circuit voltage is vth = −g mv R2 and v = +is R1. ( )( ) vth = −g m R1 R2is = −(0.0025) 105 106 i s= 2.5 x 108 is For is = 0, v = 0 and Rth = R2 = 1 MΩ 1.30 5V 3V f (Hz) 0 0 500 1000 1.31 2V 0 f (kHz) 9 10 11 [ ] 4 cos(20000πt + 2000πt )+ cos(20000πt − 2000πt ) 2 v = 2cos(22000πt )+ 2cos(18000πt ) v = 4sin (20000πt )sin (2000πt )= 1.32 2∠36 o A = −5 0 = 2x105 ∠36 o 10 ∠0 A = 2x105 ∠A = 36o 1-10 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.33 (a) A = 10−1∠ −12 o 10−2 ∠ − 45o o A = = 5∠ − 45 = 100∠ −12 o (b) 2x10−3 ∠0 o 10−3 ∠0 o 1.34 (a) Av = − R2 620kΩ 180kΩ =− = −44.3 (b) Av = − = −10.0 14kΩ R1 18kΩ (c) Av = − 62kΩ = −38.8 1.6kΩ 1.35 vo (t ) = − IS = R2 v s (t )= (−90.1 sin 750πt ) mV R1 VS 0.01V = = 11.0μA and R1 910Ω is = (11.0 sin 750πt ) μA 1.36 Since the voltage across the op amp input terminals must be zero, v- = v+ and vo = vs. Therefore Av = 1. 1.37 Since the voltage across the op amp input terminals must be zero, v- = v+ = vs. Also, i- = 0. v v− − vo + i− + − = 0 R2 R1 or vs − v o vs + =0 R2 R1 and A v = vo R = 1+ 2 vs R1 1.38 Writing a nodal equation at the inverting input terminal of the op amp gives v −v v1 − v− v2 − v− + = i− + − o R1 R2 R3 vo = − but v- = v+ = 0 and i- = 0 R3 R v1 − − 3 v2 = −0.255sin 3770t − 0.255sin10000t volts R1 R2 1-11 6/9/06 1.39 ⎛b b b ⎞ ⎛ 0 1 1⎞ ⎛ 1 0 0⎞ vO = −VREF ⎜ 1 + 2 + 3 ⎟ (a) vO = −5⎜ + + ⎟ = −1.875V (b) vO = −5⎜ + + ⎟ = −2.500V ⎝2 4 8⎠ ⎝ 2 4 8⎠ ⎝ 2 4 8⎠ b1b2b vO (V) 3 000 0 001 -0.625 010 -1.250 011 -1.875 100 -2.500 101 -3.125 110 -3.750 111 -4.375 1.40 Low-pass amplifier Amplitude 10 f 6 kHz 1-12 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.41 Band-pass amplifier Amplitude 20 f 1 kHz 1.42 5 kHz High-pass amplifier Amplitude 16 f 10 kHz 1.43 vO (t ) = 10x5sin (2000πt )+ 10x3cos(8000πt )+ 0x3cos(15000πt ) [ ] vO (t ) = 50sin(2000πt )+ 30cos(8000πt ) volts 1.44 vO (t ) = 20x0.5sin (2500πt )+ 20x0.75cos(8000πt )+ 0x0.6cos(12000πt ) [ ] vO (t ) = 10.0sin (2500πt )+ 15.0cos(8000πt ) volts 1.45 The gain is zero at each frequency: vo(t) = 0. 1-13 6/9/06 1.46 t=linspace(0,.005,1000); w=2*pi*1000; v=(4/pi)*(sin(w*t)+sin(3*w*t)/3+sin(5*w*t)/5); v1=5*v; v2=5*(4/pi)*sin(w*t); v3=(4/pi)*(5*sin(w*t)+3*sin(3*w*t)/3+sin(5*w*t)/5); plot(t,v) plot(t,v1) plot(t,v2) plot(t,v3) 2 1 0 -1 -2 0 1 2 3 4 5 x10-3 1 2 3 4 5 x10-3 (a) 10 5 0 -5 -10 0 (b) 1-14 ©R. C. Jaeger & T. N. Blalock 6/9/06 10 5 0 -5 -10 0 1 2 3 4 (c) 5 x10-3 10 5 0 -5 -10 0 1 2 3 4 5 x10-3 (d) 1.47 (a) 3000(1− .01)≤ R ≤ 3000(1+ .01) or 2970Ω ≤ R ≤ 3030Ω (b) 3000(1− .05)≤ R ≤ 3000(1+ .05) or 2850Ω ≤ R ≤ 3150Ω (c) 3000(1− .10) ≤ R ≤ 3000(1+ .10) or 2700Ω ≤ R ≤ 3300Ω ΔV ≤ 0.05V 0.05 = 0.0200 or 2.00% 2.50 1.48 Vnom = 2.5V 1.49 20000μF (1− .5)≤ C ≤ 20000μF (1+ .2) or 10000μF ≤ R ≤ 24000μF 1.50 8200(1− 0.1)≤ R ≤ 8200(1+ 0.1) or 7380Ω ≤ R ≤ 9020Ω The resistor is within the allowable range of values. T= 1-15 6/9/06 1.51 (a) 5V (1− .05)≤ V ≤ 5V (1+ .05) or 5.75V ≤ V ≤ 5.25V V = 5.30 V exceeds the maximum range, so it is out of the specification limits. (b) If the meter is reading 1.5% high, then the actual voltage would be 5.30 Vmeter = 1.015Vact or Vact = = 5.22V which is within specifications limits. 1.015 1.52 Ω ΔR 6562 − 6066 = = 4.96 o 100 − 0 ΔT C = R o + TCR (ΔT)= 6066 + 4.96(27)= 6200Ω TCR = R nom 0 C 1-16 ©R. C. Jaeger & T. N. Blalock 6/9/06 1.53 V1 + I2 R 1 R2 V I3 + R V2 3 - Let RX = R2 R3 R min X = V1max = I1 = I2min = I3 = I1 I3max = I3min = R1 = R1 + RX 47kΩ(0.9)(180kΩ)(0.9) 47kΩ(0.9)+ 180kΩ(0.9) 10(1.05) 33.5kΩ 1+ 22kΩ(1.1) V R1 + RX I2max = then V1 = V = 4.40V and I2 = I1 V1 R 1+ X R1 = 33.5kΩ R max = X V1min = R3 = R2 + R3 47kΩ(1.1)(180kΩ)(1.1) 47kΩ(1.1)+ 180kΩ(1.1) 10(0.95) 41.0kΩ 1+ 22kΩ(0.9) = 3.09V V R1 + R2 + R1 R2 R3 10(1.05) 22000(0.9)(47000)(0.9) 22000(0.9)+ 47000(0.9)+ 10(0.95) 22000(1.1)+ 47000(1.1)+ R2 = R2 + R3 = 41.0kΩ = 158 μA 180000(1.1) 22000(1.1)(47000)(1.1) = 114 μA 180000(0.9) V R1 + R3 + R1 R3 R2 10(1.05) 22000(0.9)+ 180000(0.9)+ 22000(0.9)(180000)(0.9) 10(0.95) 22000(1.1)+ 180000(1.1)+ = 43.1 μA 47000(1.1) 22000(1.1)(180000)(1.1) = 28.3 μA 47000(0.9) 1-17 6/9/06 1.54 I1 = I R2 + R3 =I R1 + R2 + R3 1+ and similarly I2 = I R1 R2 + R3 mA = 4.12 mA 2400(0.95) 1+ 1 R + R3 1+ 2 R1 I1min = 1+ 5600(1.05)+ 3600(1.05) 5(1.02) I2max = 5600(0.95)+ 3600(0.95) V3 = I2 R3 = V3min = 1+ 5(1.02) I1max = V3max = 1 mA = 1.14 mA 2400(1.05) 1+ mA = 3.80 mA 5600(0.95)+ 3600(0.95) 5(0.98) I2min = 2400(1.05) 5(0.98) 5600(1.05)+ 3600(1.05) mA = 0.936 mA 2400(0.95) I 1 1 R + + 2 R1 R3 R1 R3 5(1.02) 5600(0.95) 1 1 + + 2400(1.05) 3600(1.05) 2400(1.05)(3600)(1.05) 5(0.98) = 4.18 V 5600(1.05) 1 1 + + 2400(0.95) 3600(0.95) 2400(0.95)(3600)(0.95) = 3.30 V 1.55 Rth = From Prob. 1.24 : Rthmax = 1 gm + 1 1 0.002(0.8)+ 5x10 4 (1.2) 1 R1 = 619 Ω Rthmin = 1-18 1 1 0.002(1.2)+ 5x10 4 (0.8) = 412 Ω ©R. C. Jaeger & T. N. Blalock 6/9/06 1.56 For one set of 200 cases using the equations in Prob. 1.53. V = 10 * (0.95 + 0.1* RAND()) R1 = 22000 * (0.9 + 0.2 * RAND()) R1 = 4700 * (0.9 + 0.2 * RAND()) R3 = 180000 * (0.9 + 0.2 * RAND()) V1 I2 I3 Min 3.23 V 116 μA 29.9 μA Max 3.71 V 151 μA 40.9 μA Average 3.71 V 133 μA 35.1 μA 1.57 For one set of 200 cases using the Equations in Prob. 1.54: I = 0.005* (0.98 + 0.04 * RAND()) R1 = 2400 * (0.95 + 0.1* RAND()) R1 = 5600 * (0.95 + 0.1* RAND()) R3 = 3600 * (0.95 + 0.1* RAND()) I1 I2 V3 Min 3.82 mA 0.96 mA 3.46 V Max 4.09 mA 1.12 mA 4.08 V Average 3.97 mA 1.04 mA 3.73 V 1.58 3.29, 0.995, -6.16; 3.295, 0.9952, -6.155 1.59 (a) (1.763 mA)(20.70 kΩ) = 36.5 V (b) 36 V (c) (0.1021 A)(97.80 kΩ) = 9.99 V; 10 V 1-19 6/9/06 CHAPTER 2 2.1 Based upon Table 2.1, a resistivity of 2.6 μΩ-cm < 1 mΩ-cm, and aluminum is a conductor. 2.2 Based upon Table 2.1, a resistivity of 1015 Ω-cm > 105 Ω-cm, and silicon dioxide is an insulator. 2.3 I max ⎛ 10−8 cm2 ⎞ ⎛ 7 A ⎞ = ⎜10 ⎟ = 500 mA ⎟(5μm)(1μm)⎜ 2 cm 2 ⎠ ⎝ ⎝ μm ⎠ 2.4 EG ⎛ ⎞ ni = BT 3 exp⎜ − ⎟ −5 ⎝ 8.62 x10 T ⎠ 31 For silicon, B = 1.08 x 10 and EG = 1.12 eV: -10 3 ni = 2.01 x10 /cm 9 3 13 6.73 x10 /cm 30 For germanium, B = 2.31 x 10 and EG = 0.66 eV: 3 13 ni = 35.9/cm 3 2.27 x10 /cm 15 function f=temp(T) ni=1E14; f=ni^2-1.08e31*T^3*exp(-1.12/(8.62e-5*T)); 14 3 16 ni = 10 /cm3 for T = 739 K for T = 506 K 2.6 ⎛ ⎞ EG ni = BT 3 exp⎜ − −5 ⎟ ⎝ 8.62x10 T ⎠ with B = 1.27x1029 K −3cm−6 6 3 T = 300 K and EG = 1.42 eV: ni = 2.21 x10 /cm 3 T = 100 K: ni = 6.03 x 10-19/cm 20 3 8.04 x 10 /cm . 2.5 Define an M-File: ni = 10 /cm 3 8.36 x 10 /cm . 11 3 T = 500 K: ni = 2.79 x10 /cm 2.7 ⎛ cm2 ⎞⎛ V ⎞ 6 cm vn = −μn E = ⎜ −700 ⎟⎜ 2500 ⎟ = −1.75x10 V − s ⎠⎝ cm ⎠ s ⎝ ⎛ V ⎞ cm2 ⎞⎛ 5 cm v p = +μ p E = ⎜ +250 ⎟⎜ 2500 ⎟ = +6.25x10 cm ⎠ V − s ⎠⎝ s ⎝ ⎛ 1 ⎞⎛ cm ⎞ 4 A jn = −qnvn = −1.60x10−19 C ⎜1017 3 ⎟⎜ −1.75x106 ⎟ = 2.80x10 s ⎠ cm ⎠⎝ cm2 ⎝ ⎛ 1 ⎞⎛ cm ⎞ −10 A j p = qnv p = 1.60x10−19 C ⎜103 3 ⎟⎜ 6.25x105 ⎟ = 1.00x10 s ⎠ cm 2 ⎝ cm ⎠⎝ ( ) ( ) 2.8 ⎛ E ⎞ ni2 = BT 3 exp⎜ − G ⎟ ⎝ kT ⎠ B = 1.08x1031 ⎛ ⎞ 1.12 T 3 exp⎜ − ⎟ ⎝ 8.62x10−5 T ⎠ Using a spreadsheet, solver, or MATLAB yields T = 305.22K (10 ) = 1.08x10 10 2 31 Define an M-File: function f=temp(T) f=1e20-1.08e31*T^3*exp(-1.12/(8.62e-5*T)); Then: fzero('temp',300) | ans = 305.226 K 2.9 v= j − 1000 A / cm 2 cm = = − 105 2 Q s 0.01C / cm 2.10 C ⎞⎛ cm ⎞ MA ⎛ 6 A j = Qv = ⎜ 0.4 3 ⎟⎜10 7 =4 2 ⎟ = 4 x10 2 cm ⎠⎝ sec ⎠ cm cm ⎝ 21 2.11 ⎛ V ⎞ cm2 ⎞⎛ 6 cm vn = −μn E = ⎜−1000 ⎟⎜ −2000 ⎟ = +2.00x10 V − s ⎠⎝ cm ⎠ s ⎝ ⎛ V ⎞ cm 2 ⎞⎛ 5 cm v p = +μ p E = ⎜ +400 ⎟⎜ −2000 ⎟ = −8.00x10 V − s ⎠⎝ cm ⎠ s ⎝ ⎛ 1 ⎞⎛ cm ⎞ −10 A jn = −qnvn = −1.60x10−19 C ⎜103 3 ⎟⎜ +2.00x106 ⎟ = −3.20x10 s ⎠ cm2 ⎝ cm ⎠⎝ ⎛ 1 ⎞⎛ cm ⎞ 4 A j p = qnv p = 1.60x10−19 C ⎜1017 3 ⎟⎜ −8.00x105 ⎟ = −1.28x10 s ⎠ cm ⎠⎝ cm2 ⎝ ( ) ( ) 2.12 (a ) E= V 5V = 5000 −4 cm 10 x10 cm (b ) ( ) V ⎞ ⎛ −4 V = ⎜105 ⎟ 10 x10 cm = 100 V cm ⎝ ⎠ 2.13 ⎛ 1019 ⎞⎛ cm ⎞ 7 A j p = qpv p = 1.60x10−19 C ⎜ 3 ⎟⎜10 7 ⎟ = 1.60x10 s ⎠ cm2 ⎝ cm ⎠⎝ ⎛ A ⎞ i p = j p A = ⎜1.60x10 7 2 ⎟ 1x10−4 cm 25x10−4 cm = 4.00 A cm ⎠ ⎝ ( ) ( )( ) 2.14 For intrinsic silicon, σ = q (μn ni + μ p ni )= qni (μn + μ p ) σ ≥ 1000(Ω − cm) for a conductor −1 ni ≥ σ q (μn + μ p ) 1000(Ω − cm) −1 = cm 2 1.602x10−19 C (100 + 50) v − sec 39 ⎛ ⎞ 1.73x10 E n 2i = = BT 3 exp⎜ − G ⎟ with 6 cm ⎝ kT ⎠ = 4.16x1019 cm3 B = 1.08x1031 K −3cm−6 , k = 8.62x10-5 eV/K and EG = 1.12eV This is a transcendental equation and must be solved numerically by iteration. Using the HP solver routine or a spread sheet yields T = 2701 K. Note that this temperature is far above the melting temperature of silicon. 22 2.15 For intrinsic silicon, σ = q (μn ni + μ p ni )= qni (μn + μ p ) σ ≤ 10−5 (Ω − cm) for an insulator −1 ni ≥ σ q (μn + μ p ) 10−5 (Ω − cm) −1 = ⎛ cm 2 ⎞ 1.602x10 C (2000 + 750)⎜ ⎟ ⎝ v − sec ⎠ ⎛ E ⎞ 5.152x1020 n 2i = = BT 3 exp⎜ − G ⎟ with 6 cm ⎝ kT ⎠ ( −19 ) = 2.270x1010 cm 3 B = 1.08x1031 K −3cm−6 , k = 8.62x10-5 eV/K and EG = 1.12eV Using MATLAB as in Problem 2.5 yields T = 316.6 K. 2.16 Si Si Si P B Si Si Si Si Donor electron fills acceptor vacancy No free electrons or holes (except those corresponding to ni). 2.17 (a) Gallium is from column 3 and silicon is from column 4. Thus silicon has an extra electron and will act as a donor impurity. (b) Arsenic is from column 5 and silicon is from column 4. Thus silicon is deficient in one electron and will act as an acceptor impurity. 2.18 Since Ge is from column IV, acceptors come from column III and donors come from column V. (a) Acceptors: B, Al, Ga, In, Tl (b) Donors: N, P, As, Sb, Bi 23 2.19 (a) Germanium is from column IV and indium is from column III. Thus germanium has one extra electron and will act as a donor impurity. (b) Germanium is from column IV and phosphorus is from column V. Thus germanium has one less electron and will act as an acceptor impurity. 2.20 A ⎞ V ⎛ = jρ = ⎜10000 2 ⎟(0.02Ω − cm ) = 200 , a small electric field. cm ⎠ σ cm ⎝ j E= 2.21 ⎛ C ⎞⎛ cm ⎞ A jndrift = qnμn E = qnv n = 1.602x10−19 1016 ⎜ 3 ⎟⎜10 7 ⎟ = 16000 2 s ⎠ cm ⎝ cm ⎠⎝ ( )( ) 2.22 ⎛ 1015 atoms ⎞ ⎛ 10−4 cm ⎞3 N =⎜ ⎟(1μm)(10μm)(0.5μm )⎜ ⎟ = 5,000 atoms 3 ⎝ cm ⎠ ⎝ μm ⎠ 2.23 N A > N D : N A − N D = 1015 −1014 = 9x1014 /cm3 If we assume N A − N D >> 2ni = 1014 / cm 3 : p = N A − N D = 9x1014 /cm3 | n = If we use Eq. 2.12 : p = 9x1014 ± ni2 251026 = = 2.78x1012 /cm3 p 9x1014 (9x10 ) + 4(5x10 ) = 9.03x10 14 2 13 2 14 2 and n = 2.77x10 /cm . The answers are essentially the same. 12 3 2.24 N A > N D: N A − N D = 5 x1016 − 1016 = 4 x1016 /cm 3 >> 2ni = 2 x1011 /cm 3 p = N A − N D = 4 x1014 /cm 3 | n = ni2 10 22 = = 2.50 x10 5 /cm 3 p 4 x1016 2.25 N D > N A: N D − N A = 3x1017 − 2x1017 = 1x1017 /cm3 2ni = 2x1017 /cm3 ; Need to use Eq. (2.11) n= p= 24 1017 ± ( ) ( ) = 1.62x10 2 1017 + 4 1017 2 2 2 i 34 n 10 = = 6.18x1016 /cm3 n 1.62x1017 17 /cm3 2.26 N D − N A = −2.5x1018 / cm 3 Using Eq. 2.11: n = −2.5x1018 ± (−2.5x10 ) + 4(10 ) 18 2 10 2 2 ni2 = ∞. p No, the result is incorrect because of loss of significant digits Evaluating this with a calculator yields n = 0, and n = within the calculator. It does not have enough digits. 2.27 (a) Since boron is an acceptor, NA = 6 x 1018/cm3. Assume ND = 0, since it is not specified. The material is p-type. At room temperature, ni = 1010 /cm3 and N A − N D = 6 x1018 / cm3 >> 2n i ni2 10 20 /cm 6 So p = 6 x10 /cm and n = = = 16.7 /cm3 18 3 p 6 x10 /cm (b) ⎛ ⎞ 3 1.12 ⎟ At 200K, ni2 = 1.08x1031 (200) exp⎜⎜ − = 5.28x109 /cm6 −5 ⎟ ⎝ 8.62x10 (200)⎠ 18 3 ni = 7.27x10 4 /cm 3 N A − N D >> 2ni , so p = 6x1018 /cm3 and n = 5.28x109 = 8.80x10−10 /cm 3 18 6x10 2.28 (a) Since arsenic is a donor, ND = 3 x 1017/cm3. Assume NA = 0, since it is not specified. The material is n-type. At room temperature, n i = 1010 / cm 3 and N D − N A = 3 x1017 / cm 3 >> 2n i 10 20 /cm 6 ni2 = = 333 /cm 3 17 3 n 3x10 /cm ⎛ ⎞ 3 1.12 ⎟ = 4.53x1015 /cm6 (b) At 250K, ni2 = 1.08x1031 (250) exp⎜⎜− −5 ⎟ ⎝ 8.62x10 (250)⎠ So n = 3 x1017 /cm 3 and p = ni = 6.73x10 7 /cm 3 N D − N A >> 2ni , so n = 3x1017 / cm 3 and n = 4.53x1015 = 0.0151/ cm 3 17 3x10 2.29 (a) Arsenic is a donor, and boron is an acceptor. ND = 2 x 1018/cm3, and NA = 8 x 1018/cm3. Since NA > ND, the material is p-type. 25 (b) At room temperature, n i = 1010 / cm3 and N A − N D = 6 x1018 / cm3 >> 2n i ni2 10 20 /cm 6 So p = 6 x10 /cm and n = = = 16.7 /cm3 18 3 p 6 x10 /cm 18 3 2.30 (a) Phosphorus is a donor, and boron is an acceptor. ND = 2 x 1017/cm3, and NA = 5 x 1017/cm3. Since NA > ND, the material is p-type. (b) At room temperature, ni = 1010 /cm3 and N A − N D = 3x1017 / cm3 >> 2n i ni2 10 20 /cm 6 So p = 3x10 /cm and n = = = 333 /cm3 17 3 p 3x10 /cm 17 3 2.31 ND = 4 x 1016/cm3. Assume NA = 0, since it is not specified. N D > N A : material is n - type | N D − N A = 4x1016 / cm3 >> 2ni = 2x1010 / cm 3 n = 4x1016 / cm3 | p = n 2i 1020 = = 2.5x103 / cm 3 16 n 4x10 N D + N A = 4x1016 / cm3 | Using Fig. 2.13, μn = 1030 ρ= 26 1 qμn n = 1 ⎛ cm 2 ⎞⎛ 4x1016 ⎞ 1.602x10 C ⎜1030 ⎟⎜ ⎟ V − s ⎠⎝ cm 3 ⎠ ⎝ ( −19 ) cm2 cm 2 and μp = 310 V −s V −s = 0.152 Ω − cm 2.32 NA = 1018/cm3. Assume ND = 0, since it is not specified. N A > N D : material is p - type | N A − N D = 1018 / cm3 >> 2ni = 2x1010 / cm 3 p = 1018 / cm3 | n= n 2i 1020 = 18 = 100 / cm 3 p 10 cm2 cm 2 N D + N A = 10 / cm | Using Fig. 2.13, μn = 375 and μp = 100 V −s V −s 1 1 ρ= = = 0.0624 Ω − cm ⎛ qμ p p cm 2 ⎞⎛ 1018 ⎞ −19 1.602x10 C⎜100 ⎟⎜ ⎟ V − s ⎠⎝ cm 3 ⎠ ⎝ 18 3 2.33 Indium is from column 3 and is an acceptor. NA = 7 x 1019/cm3. Assume ND = 0, since it is not specified. N A > N D : material is p - type | N A − N D = 7x1019 /cm3 >> 2ni = 2x1010 /cm3 p = 7x1019 /cm3 | n= ni2 1020 = = 1.43/cm3 19 p 7x10 cm2 cm 2 N D + N A = 7x10 / cm | Using Fig. 2.13, μn = 120 and μp = 60 V −s V −s 1 1 ρ= = = 1.49 mΩ − cm ⎛ qμ p p cm 2 ⎞⎛ 7x1019 ⎞ −19 1.602x10 C⎜ 60 ⎟⎜ 3 ⎟ ⎝ V − s ⎠⎝ cm ⎠ 19 3 2.34 Phosphorus is a donor : N D = 5.5x1016 / cm 3 | Boron is an acceptor : N A = 4.5x1016 / cm 3 N D > N A : material is n - type | N D − N A = 1016 / cm3 >> 2ni = 2x1010 / cm 3 ni2 1020 n = 10 /cm | p = = 16 = 10 4 /cm3 p 10 16 3 cm2 cm 2 N D + N A = 10 / cm | Using Fig. 2.13, μn = 800 and μp = 230 V −s V −s 1 1 ρ= = = 0.781 Ω − cm ⎛ qμ n n cm 2 ⎞⎛ 1016 ⎞ −19 1.602x10 C⎜ 800 ⎟⎜ ⎟ V − s ⎠⎝ cm 3 ⎠ ⎝ 17 27 3 2.35 1 ρ= qμ p p | μp p = 1 (1.602x10 C)(0.054Ω − cm) −19 = 1.16x1020 V − cm − s An iterative solution is required. Using the equations in Fig. 2.8: NA μp μp p 1018 96.7 9.67 x 1020 1.1 x1018 93.7 1.03 x 1020 1.2 x 1017 91.0 1.09 x 1020 1.3 x 1019 88.7 1.15 x 1020 2.36 8.32x1018 ρ= | μp p = = qμ p p 1.602x10−19 C (0.75Ω − cm) V − cm − s 1 1 ( ) An iterative solution is required. Using the equations in Fig. 2.8: μp NA 1016 μp p 406 4.06 x 1018 2 x 1016 363 7.26 x 1018 3 x 1016 333 1.00 x 1019 2.4 x 1016 350 8.40 x 1018 2.37 Based upon the value of its resistivity, the material is an insulator. However, it is not intrinsic because it contains impurities. Addition of the impurities has increased the resistivity. 2.38 ρ= 1 qμn n | μ n n ≈ μn N D = 1 (1.602x10 C)(2Ω − cm) −19 = 3.12x1018 V − cm − s An iterative solution is required. Using the equations in Fig. 2.8: ND μn μnn 1015 1350 1.35 x 1018 2 x 1015 1330 2.67 x 1018 2.5 x 1015 1330 3.32 x 1018 28 2.3 x 1015 29 1330 3.06 x 1018 2.39 (a) 1 1 6.24x1021 ρ= | μn n ≈ μn N D = = qμn n 1.602x10−19 C (0.001Ω − cm) V − cm − s ( ) An iterative solution is required. Using the equations in Fig. 2.8: ND μn μnn 1019 116 1.16 x 1021 7 x 1019 96.1 6.73 x 1021 6.5 x 1019 96.4 6.3 x 1021 (b) ρ= 1 qμ p p | μp p ≈ μp N A = 1 6.24 x10 21 = (1.602x10−19 C)(0.001Ω − cm) V − cm − s An iterative solution is required using the equations in Fig. 2.8: NA 1.3 x 1020 μp μp p 49.3 6.4 x 1021 2.40 Yes, by adding equal amounts of donor and acceptor impurities the mobilities are reduced, but the hole and electron concentrations remain unchanged. See Problem 2.37 for example. However, it is physically impossible to add exactly equal amounts of the two impurities. 2.41 (a) For the 1 ohm-cm starting material: 1 1 6.25x1018 ρ= | μp p ≈ μpN A = = qμ p p 1.602x10−19 C (1Ω − cm) V − cm − s ( ) An iterative solution is required. Using the equations in Fig. 2.8: NA μp μp p 1016 406 4.1 x 1018 1.5 x 1016 383 5.7 x 1018 1.7 x 1016 374 6.4 x 1019 30 To change the resistivity to 0.25 ohm-cm: 1 1 2.5x1019 ρ= | μp p ≈ μpN A = = qμ p p 1.602x10−19 C (0.25Ω − cm) V − cm − s ( ) NA μp μp p 6 x 1016 276 1.7 x 1019 8 x 1016 233 2.3 x 1019 1.1 x 1017 225 2.5 x 1019 17 16 16 3 Additional acceptor concentration = 1.1x10 - 1.7x10 = 9.3 x 10 /cm (b) If donors are added: ND ND + NA μn ND - NA μnn 2 x 1016 3.7 x 1016 1060 3 x 1015 3.2 x 1018 1 x 1017 1.2 x 1017 757 8.3 x 1016 6.3 x 1019 8 x 1016 9.7 x 1016 811 6.3 x 1016 5.1 x 1019 4.1 x 1016 5.8 x 1016 950 2.4 x 1016 2.3 x 1019 16 3 So ND = 4.1 x 10 /cm must be added to change achieve a resistivity of 0.25 ohm-cm. The silicon is converted to n-type material. 2.42 Phosphorus is a donor: ND = 1016/cm3 and μn = 1250 cm2/V-s from Fig. 2.8. 2.00 σ = qμn n ≈ qμn N D = 1.602x10−19 C (1250) 1016 = Ω − cm -1 Now we add acceptors until σ = 5.0 (Ω-cm) : ( ) ( ) 5(Ω − cm) −1 σ = qμ p p | 3.12x1019 μ p p ≈ μ p (N A − N D )= = 1.602x10−19 C V − cm − s NA ND + NA μp NA - ND μp p 1 x 1017 1.1 x 1017 250 9 x 1016 2.3 x 1019 2 x 1017 2.1 x 1017 176 1.9 x 1017 3.3 x 1019 1.8 x 1017 1.9 x 1017 183 1.7 x 1016 3.1 x 1019 31 2.43 Boron is an acceptor: NA = 1016/cm3 and μp = 405 cm2/V-s from Fig. 2.8. 0.649 σ = qμ p p ≈ qμ p N A = 1.602x10−19 C (405) 1016 = Ω − cm -1 Now we add donors until σ = 5.5 (Ω-cm) : ( ) ( ) 5.5(Ω − cm) −1 σ = qμ n n | μn n ≈ μn (N D − N A )= 1.602x10−19 C = 3.43x1019 V − cm − s ND ND + NA μn ND - NA μp p 8 x 1016 9 x 1016 832 7 x 1016 5.8 x 1019 7 x 1016 901 5 x 1016 4.5 x 1019 5.5 x 1016 964 3.5 x 1016 3.4 x 1019 6 x 1016 4.5 x 1016 2.44 VT = kT 1.38x10−23 T = = 8.62x10−5 T q 1.602x10−19 T (K) 50 75 100 150 200 250 300 350 400 VT (mV) 4.31 6.46 8.61 12.9 17.2 21.5 25.8 30.1 34.5 2.45 ⎛ dn ⎞ dn j = −qDn ⎜− ⎟ = qVT μn dx ⎝ dx ⎠ ⎛ cm2 ⎞⎛ 1018 − 0 ⎞ 1 kA j = 1.602x10−19 C (0.025V )⎜ 350 = −14.0 2 ⎟⎜ −4 ⎟ 4 V − s ⎠⎝ 0 −10 ⎠ cm cm ⎝ ( ) 2.46 ⎛ cm2 ⎞⎛ 1019 / cm 3 ⎞ ⎛ ⎞ dp x = −1.602x10−19 C ⎜15 ⎟⎜ − ⎟ exp⎜− ⎟ −4 −4 s ⎠⎝ 2x10 cm ⎠ ⎝ 2x10 cm ⎠ dx ⎝ ⎛ x ⎞ A j = 1.20x105 exp⎜−5000 ⎟ 2 cm ⎠ cm ⎝ ⎛ 10−8 cm2 ⎞ ⎛ A ⎞ I (0)= j (0)A = ⎜1.20x105 2 ⎟ 10μm2 ⎜ ⎟ = 12.0 mA 2 cm ⎠ ⎝ ⎝ μm ⎠ j = −qD p ( ) ( 32 ) 2.47 j p = qμ p pE − qD p ⎛ dp 1 dp ⎞ 1 dp = qμ p p⎜ E − VT ⎟ = 0 → E = VT dx p dx ⎠ p dx ⎝ ( ) −1022 exp −10 4 x 1 dN A E ≈ VT = 0.025 14 N A dx 10 + 1018 exp −10 4 x E (0)= −0.025 ( ) 22 10 V = −250 18 cm 10 + 10 22 10 exp(−5) V E 5x10−4 cm = −0.025 14 = −246 18 cm 10 + 10 exp(−5) ( 14 ) 2.48 ⎛ V ⎞ cm2 ⎞⎛ 1016 ⎞⎛ A jndrift = qμn nE = 1.60x10−19 C ⎜350 ⎟⎜ 3 ⎟⎜ −20 ⎟ = −11.2 2 cm ⎠ V − s ⎠⎝ cm ⎠⎝ cm ⎝ ⎛ V ⎞ cm2 ⎞⎛1.01x1018 ⎞⎛ A drift −19 −20 j p = qμ p pE = 1.60x10 C ⎜150 ⎟⎜ ⎟ ⎜ ⎟ = −484 2 3 cm ⎠ V − s ⎠⎝ cm cm ⎝ ⎠⎝ ⎛ A cm2 ⎞⎛ 10 4 −1016 ⎞ dn = −70.0 2 jndiff = qDn = 1.60x10−19 C ⎜ 350 ⋅ 0.025 ⎟⎜ −4 4⎟ s ⎠⎝ 2x10 cm ⎠ dx cm ⎝ ⎛ A cm2 ⎞⎛ 1018 −1.01x1018 ⎞ dp j pdiff = −qD p = −1.60x10−19 C ⎜150 ⋅ 0.025 ⎟⎜ ⎟ = 30.0 2 −4 4 s ⎠⎝ 2x10 cm ⎠ dx cm ⎝ A jT = −11.2 − 484 − 70.0 + 30.0 = −535 2 cm ( ) ( ) ( ) ( 2.49 ) NA = 2ND EC ED N D ND ND EA NA NA NA E V Holes 2.50 ( )( ) ) −34 8 hc 6.626x10 J − s 3x10 m / s λ= = = 1.108 μm E (1.12eV ) 1.602x10−19 J / eV 33 ( NA 2.51 Al - Anode Al - Cathode Si02 n-type silicon p-type silicon 2.52 An n-type ion implantation step could be used to form the n+ region following step (f) in Fig. 2.17. A mask would be used to cover up the opening over the p-type region and leave the opening over the n-type silicon. The masking layer for the implantation could just be photoresist. Mask Ion implantation Photoresist Si02 n+ p-type silicon n-type silicon p-type silicon n-type silicon Structure following ion implantation of n-type impurity Structure after exposure and development of photoresist layer Mask for ion implantation Side view Top View 2.53 ⎛ 1⎞ ⎛ 1⎞ 1 = 8 atoms (a) N = 8⎜ ⎟ + 6⎜ ⎟ + 4() ⎝ 8⎠ ⎝ 2⎠ ( ) ( 3 ) 3 (b) V = l 3 = 0.543x10−9 m = 0.543x10−7 cm = 1.60x10−22 cm3 8 atoms atoms = 5.00x1022 1.60x1022 cm3 cm3 ⎛ g ⎞ (d ) m = ⎜ 2.33 3 ⎟1.60x1022 cm3 = 3.73x10−22 g cm ⎠ ⎝ (c) D = (e) From Table 2.2, silicon has a mass of 28.086 protons. mp = g 3.73x10−22 g = 1.66x10−24 proton 28.082(8)protons Yes, near the actual proton rest mass. 34 CHAPTER 3 3.1 1019 ⋅ cm−3 )(1018 ⋅ cm −3 ) ( NA ND φ j = VT ln 2 = (0.025V )ln = 0.979V ni 10 20 ⋅ cm −6 2(11.7 ⋅ 8.854 x10−14 F ⋅ cm−1 )⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 w do = + ⎜ 19 −3 + 18 −3 ⎟ (0.979V) ⎜ ⎟ φj = −19 ⎝ 10 cm q ⎝ NA ND ⎠ 1.602x10 C 10 cm ⎠ w do = 3.73 x 10−6 cm = 0.0373μm w do 0.0373μm w do 0.0373μm -3 xn = = = μm 18 −3 = 0.0339 μm | x p = 19 −3 = 3.39 x 10 ND N 10 10 cm cm A 1+ 1+ 1+ 19 −3 1+ 18 −3 NA ND 10 cm 10 cm E MAX = qN A x p εs (1.60x10 = −19 C )(1019 cm −3 )(3.39x10−7 cm) 11.7 ⋅ 8.854 x10 −14 F /cm = 5.24 x 10 5 V cm 3.2 p po = N A = 1018 cm 3 1015 n no = N D = cm 3 | n po = n i2 10 20 10 2 = = p po 1018 cm 3 n i2 10 20 10 5 | p no = = = n no 1015 cm 3 1018 cm−3 )(1015 cm −3 ) ( NA ND φ j = VT ln 2 = (0.025V )ln = 0.748 V ni 10 20 cm−6 w do = 2(11.7 ⋅ 8.854 x10−14 F ⋅ cm−1 )⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 + φ = ⎜ 18 −3 + 15 −3 ⎟ (0.748V) ⎜ ⎟ j −19 ⎝ 10 cm 10 cm ⎠ q ⎝ NA ND ⎠ 1.602x10 C w do = 98.4 x 10−6 cm = 0.984 μm 3.3 p po = N A = 1018 ni2 1020 102 | n = = = po p po 1018 cm3 cm3 1018 ni2 1020 102 nno = N D = 3 | p no = = = nno 1018 cm3 cm 1018 ⋅ cm−3 )(1018 ⋅ cm −3 ) ( NA ND φ j = VT ln 2 = (0.025V )ln = 0.921V ni 10 20 ⋅ cm −6 w do = 2(11.7 ⋅ 8.854 x10−14 F ⋅ cm−1 )⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 + φ = ⎜ 18 −3 + 18 −3 ⎟ (0.921V) ⎜ ⎟ j −19 ⎝ 10 cm 10 cm ⎠ q ⎝ NA ND ⎠ 1.602x10 C w do = 4.881x10−6 cm = 0.0488 μm 34 3.4 p po = N A = 1018 ni2 1020 102 | n = = = po p po 1018 cm3 cm3 1018 ni2 1020 102 | p = = = no nno 1018 cm3 cm3 (1018 ⋅ cm−3 )(1020 ⋅ cm−3 ) = 1.04V N N φ j = VT ln A 2 D = (0.025V )ln ni 10 20 ⋅ cm −6 nno = N D = 2(11.7 ⋅ 8.854 x10−14 F ⋅ cm−1 )⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 w do = + ⎜ 18 −3 + 20 −3 ⎟ (1.04V) ⎜ ⎟ φj = −19 ⎝ 10 cm 10 cm ⎠ q ⎝ NA ND ⎠ 1.602x10 C w do = 0.0369 μm 3.5 p po = N A = 1016 ni2 1020 10 4 | n = = = po p po 1016 cm3 cm3 1019 ni2 1020 10 | p = = = no nno 1019 cm3 cm3 1019 ⋅ cm−3 1016 ⋅ cm −3 N AND φ j = VT ln = (0.025V )ln = 0.864V ni2 1020 ⋅ cm −6 nno = N D = ( ( )( ) ) 2 11.7 ⋅ 8.854x10−14 F ⋅ cm−1 ⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 wdo = + ⎜ ⎟ φj = ⎜ 19 −3 + 16 −3 ⎟ (0.864V) −19 q ⎝ N A ND ⎠ 10 cm ⎠ 1.602x10 C ⎝ 10 cm wdo = 0.334 μm 3.6 wd = wdo 1+ VR φj | (a) wd = 2wdo requires VR = 3φ j = 2.55 V | wd = 0.4μm 1+ 5 = 1.05 μm 0.85 3.7 wd = wdo 1+ VR φj | (a) wd = 3wdo requires VR = 8φ j = 4.80 V | wd = 1μm 1+ 10 = 4.20 μm 0.6 3.8 jn = σE , σ = 1 ρ = 1 2 j 1000 A⋅ cm −2 V = | E= n = = 500 −1 0.5 Ω ⋅ cm Ω ⋅ cm cm σ 2(Ω ⋅ cm) 35 3.9 j p = σE | E= jn σ ( ) = jn ρ = 5000 A⋅ cm −2 (2Ω ⋅ cm)= 10.0 kV cm 3.10 ⎛ 4x1015 ⎞⎛ 10 7 cm ⎞ A j ≅ jn = qnv = 1.60x10−19 C ⎜ ⎟ = 6400 2 3 ⎟⎜ cm ⎝ cm ⎠⎝ s ⎠ ( ) 3.11 ⎛ 5x1017 ⎞⎛ 10 7 cm ⎞ kA j ≅ j p = qpv = 1.60x10−19 C ⎜ ⎟ = 800 2 3 ⎟⎜ cm ⎝ cm ⎠⎝ s ⎠ ( 3.12 j p = qμ p pE − qD p ) ⎛ D ⎞ 1 dp ⎛ kT ⎞ 1 dp dp = 0 → E = −⎜⎜ p ⎟⎟ = −⎜ ⎟ dx ⎝ q ⎠ p dx ⎝ μ p ⎠ p dx ⎛ x⎞ p( x) = N o exp⎜ − ⎟ | ⎝ L⎠ 1 dp 1 V 0.025V V = | E = − T = − −4 = −250 L p dx L cm 10 cm The exponential doping results in a constant electric field. 3.13 j p = qDn dn dn dn 2000 A/ cm 2 1.00 x 1021 = qμnVT | = = dx dx dx 1.60x10−19 C 500cm2 /V − s (0.025V ) cm 4 ( 3.14 10 = 10 4 ⋅10−16 exp(40VD )−1 + VD [ ] 3.15 f = 10 −10 4 I D − 0.025ln ID + IS IS )( ) and the solver yields VD = 0.7464 V | f ' = −10 4 − 0.025 ID + IS | I'D = I D − -13 Starting the iteration process with ID = 100 μA and IS = 10 A: ID 1.000E-04 9.275E-04 9.426E-04 9.426E-04 36 f f' 8.482E+0 0 1.512E01 3.268E06 9.992E16 -1.025E+04 -1.003E+04 -1.003E+04 -1.003E+04 f f' 3.16 (a) Create the following m-file: function fd=current(id) fd=10-1e4*id-0.025*log(1+id/1e-13); Then: fzero('current',1) yields ans = 9.4258e-04 -15 (b) Changing IS to 10 A: function fd=current(id) fd=10-1e4*id-0.025*log(1+id/1e-15); Then: fzero('current',1) yields ans = 9.3110e-04 3.17 −19 qVT 1.60x10 C (0.025V ) T= = = 290 K k 1.38x10−23 J / K 3.18 ( ) −23 kT 1.38x10 J / K T VT = = = 8.63x10−5 T −19 q 1.60x10 C For T = 218 K, 273 K and 358 K, VT = 18.8 mV, 23.6 mV and 30.9 mV 3.19 ⎡ ⎛ 40V ⎞ ⎤ D Graphing I D = I S ⎢exp⎜ ⎟ −1⎥ yields : n ⎝ ⎠ ⎦ ⎣ 6 5 (b) 4 (a) 3 2 1 (c) 0 0.0 0.2 0.4 0.6 0.8 1.0 1.2 37 3.20 ( ) 1.38x10−23 J / K (300) kT = 1.04 = 26.88 mV nVT = n q 1.60x10−19 C T = 26.88mV 1.602x10-19 = 312 K 1.38x10-23 3.21 ⎡ ⎛v ⎞ ⎤ ⎛ i ⎞ vD = ln⎜1+ D ⎟ iD = I S ⎢exp⎜ D ⎟ −1⎥ or nVT ⎝ IS ⎠ ⎣ ⎝ nVT ⎠ ⎦ ⎛i ⎞ ⎛ 1 ⎞ v For i D >> I S , D ≅ ln⎜ D ⎟ or ln (I D )= ⎜ ⎟v D + ln (IS ) nVT ⎝ IS ⎠ ⎝ nVT ⎠ which is the equation of a straight line with slope 1/nVT and x-axis intercept at -ln (IS). The -4 values of n and IS can be found from any two points on the line in the figure: e. g. iD = 10 A -9 for vD = 0.60 V and iD = 10 A for vD = 0.20 V. Then there are two equations in two unknowns: ⎛ 40 ⎞ ⎛8⎞ ln 10-9 = ⎜ ⎟.20 + ln (IS ) or 9.21 = ⎜ ⎟ + ln (IS ) ⎝n⎠ ⎝n⎠ ⎛ 40 ⎞ ⎛ 24 ⎞ ln 10-4 = ⎜ ⎟.60 + ln (IS ) or 20.72 = ⎜ ⎟ + ln (IS ) ⎝n⎠ ⎝n⎠ -12 Solving for n and IS yields n = 1.39 and IS = 3.17 x 10 A = 3.17 pA. ( ) ( ) 3.22 ⎡ ⎛V ⎞ ⎤ ⎛ I ⎞ VD = nVT ln⎜1+ D ⎟ | I D = I S ⎢exp⎜ D ⎟ −1⎥ ⎝ IS ⎠ ⎣ ⎝ nVT ⎠ ⎦ ⎛ 7x10−5 A ⎞ ⎛ 5x10−6 A ⎞ = 1.05 0.025V ln (a) VD = 1.05(0.025V )ln⎜1+ = 0.837V | (b) V ⎟ ⎜1+ ⎟ = 0.768V ( ) D 10−18 A ⎠ 10−18 A ⎠ ⎝ ⎝ ⎡ ⎛ ⎞ ⎤ 0 (c) I D = 10−18 A⎢exp⎜ ⎟ −1⎥ = 0 A ⎣ ⎝1.05⋅ 0.025V ⎠ ⎦ ⎡ ⎛ −0.075V ⎞ ⎤ −19 (d) I D = 10−18 A⎢exp⎜ ⎟ −1⎥ = −0.943x10 A ⎣ ⎝ 1.05⋅ 0.025V ⎠ ⎦ ⎡ ⎛ ⎞ ⎤ −5V −18 (e) I D = 10−18 A⎢exp⎜ ⎟ −1⎥ = −1.00x10 A ⎣ ⎝1.05⋅ 0.025V ⎠ ⎦ 3.23 ⎡ ⎛V ⎞ ⎤ ⎛ I ⎞ VD = nVT ln⎜1+ D ⎟ | I D = I S ⎢exp⎜ D ⎟ −1⎥ ⎝ IS ⎠ ⎣ ⎝ nVT ⎠ ⎦ ⎛ 10−4 A ⎞ ⎛ 10−5 A ⎞ (a) VD = 0.025V ln⎜1+ −17 ⎟ = 0.748V | (b) VD = 0.025V ln⎜1+ −17 ⎟ = 0.691V ⎝ 10 A ⎠ ⎝ 10 A ⎠ 38 ⎡ ⎛ 0 ⎞ ⎤ (c) ID = 10−17 A⎢exp⎜ ⎟ −1⎥ = 0 A ⎣ ⎝ 0.025V ⎠ ⎦ ⎡ ⎛ −0.06V ⎞ ⎤ −17 (d) ID = 10−17 A⎢exp⎜ ⎟ −1⎥ = −0.909x10 A ⎣ ⎝ 0.025V ⎠ ⎦ ⎡ ⎛ −4V ⎞ ⎤ −17 (e) ID = 10−17 A⎢exp⎜ ⎟ −1⎥ = −1.00x10 A ⎣ ⎝ 0.025V ⎠ ⎦ 3.24 ⎡ ⎛V ⎞ ⎤ ⎡ ⎛ 0.675 ⎞ ⎤ −6 I D = I S ⎢exp⎜ D ⎟ −1⎥ = 10−17 A ⎢exp⎜ ⎟ −1⎥ = 5.32x10 A = 5.32 μA ⎣ ⎝ 0.025 ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎛ 15.9x10−6 A ⎞ ⎞ ⎛I VD = VT ln⎜ D + 1⎟ = (0.025V )ln⎜ + 1⎟ = 0.703 V −17 ⎠ ⎝ IS ⎝ 10 A ⎠ 3.25 ⎛ I ⎞ ⎛ 40 A ⎞ VD = nVT ln⎜1+ D ⎟ = 2(0.025V )ln⎜1+ −10 ⎟ = 1.34 V ⎝ 10 A ⎠ ⎝ IS ⎠ ⎛ 100 A ⎞ VD = 2(0.025V )ln⎜1+ −10 ⎟ = 1.38 V ⎝ 10 A ⎠ 3.26 ID 2mA = = 1.14x10−17 A ⎡ ⎛ V ⎞ ⎤ ⎡ ⎛ 0.82 ⎞ ⎤ ⎢exp⎜ D ⎟ −1⎥ ⎢exp⎜ ⎟ −1⎥ ⎣ ⎝ nVT ⎠ ⎦ ⎣ ⎝ 0.025 ⎠ ⎦ ⎡ ⎛ −5 ⎞ ⎤ −17 (b) I D = 1.14x10−17 A ⎢exp⎜ ⎟ −1⎥ = −1.14x10 A 0.025 ⎠ ⎦ ⎣ ⎝ (a) I S = 3.27 ID 300μA = = 2.81x10−17 A ⎡ ⎛ V ⎞ ⎤ ⎡ ⎛ 0.75 ⎞ ⎤ ⎢exp⎜ D ⎟ −1⎥ ⎢exp⎜ ⎟ −1⎥ ⎣ ⎝ nVT ⎠ ⎦ ⎣ ⎝ 0.025 ⎠ ⎦ ⎡ ⎛ −3 ⎞ ⎤ −17 (b) I D = 2.81x10−17 A ⎢exp⎜ ⎟ −1⎥ = −2.81x10 A ⎣ ⎝ 0.025 ⎠ ⎦ (a) I S = 39 3.28 ⎛ I ⎞ VD = nVT ln⎜1+ D ⎟ | 10-14 ≤ I S ≤ 10−12 ⎝ IS ⎠ ⎛ 10−3 A ⎞ VD = (0.025V )ln⎜1+ −14 ⎟ = 0.633 V ⎝ 10 A ⎠ 3.29 | ⎛ 10−3 A ⎞ VD = (0.025V )ln⎜1+ −12 ⎟ = 0.518 V ⎝ 10 A ⎠ | So, 0.518 V ≤ VD ≤ 0.633 V 1.38x10−23 (307) ⎡ ⎛ V ⎞ ⎤ D = 0.0264V | I = I exp ⎢ ⎟ −1⎥ ⎜ D S 1.60x10−19 ⎣ ⎝ 0.0264n ⎠ ⎦ Varying n and IS by trial-and-error with a spreadsheet: VT = n IS 1.039 7.606E-15 VD ID-Measured ID-Calculated Error Squared 0.500 0.550 0.600 0.650 0.675 0.700 0.725 0.750 0.775 6.591E-07 3.647E-06 2.158E-05 1.780E-04 3.601E-04 8.963E-04 2.335E-03 6.035E-03 1.316E-02 6.276E-07 3.885E-06 2.404E-05 1.488E-04 3.702E-04 9.211E-04 2.292E-03 5.701E-03 1.418E-02 9.9198E-16 5.6422E-14 6.0672E-12 8.518E-10 1.0261E-10 6.1409E-10 1.8902E-09 1.1156E-07 1.0471E-06 Total Squared Error 3.30 ( 1.1622E-06 ) −23 kT 1.38x10 J / K T = = 8.63x10−5 T VT = q 1.60x10−19 C For T = 233 K, 273 K and 323 K, VT = 20.1 mV, 23.6 mV and 27.9 mV 3.31 −23 ⎛ 10−3 ⎞ kT 1.38x10 (303) = = 26.1 mV | V = 0.0261V ln 1+ = 0.757 V ⎜ ( ) D −16 ⎟ q 1.60x10−19 ⎝ 2.5x10 ⎠ ΔV = (−1.8mV / K )(20K ) = −36.0 mV | VD = 0.757 − 0.036 = 0.721 V 40 3.32 −23 ⎛ 10−4 ⎞ kT 1.38x10 (298) = = 25.67 mV | (a) VD = (0.02567V )ln⎜1+ −15 ⎟ = 0.650 V q 1.602x10−19 ⎝ 10 ⎠ ΔV = (−2.0mV / K )(25K ) = −50.0 mV (b) VD = 0.650 − 0.050 = 0.600 V 3.33 −23 ⎛ 2.5x10−4 ⎞ kT 1.38x10 (298) = = 25.67 mV | (a) V = 0.02567V ln ( ) ⎜1+ 10−14 ⎟ = 0.615 V D q 1.602x10−19 ⎝ ⎠ (b) ΔV = (−1.8mV / K )(60K )= −50.0 mV (c) ΔV = (−1.8mV / K )(−80K )= +144 mV VD = 0.615 − 0.108 = 0.507 V VD = 0.615 + 0.144 = 0.758 V 3.34 mV dvD vD − VG − 3VT 0.7 −1.21− 3(0.0259) = = = −1.96 dT T 300 K 41 3.35 3 ⎡ ⎛ E ⎞⎛ 1 1 ⎞⎤ ⎛ T ⎞3 ⎡⎛ E ⎞⎛ T ⎞⎤ I S 2 ⎛ T2 ⎞ = ⎜ ⎟ exp⎢−⎜ G ⎟⎜ − ⎟⎥ = ⎜ 2 ⎟ exp⎢⎜ G ⎟⎜1− 1 ⎟⎥ I S1 ⎝ T1 ⎠ ⎣ ⎝ k ⎠⎝ T2 T1 ⎠⎦ ⎝ T1 ⎠ ⎣⎝ kT1 ⎠⎝ T2 ⎠⎦ ⎡⎛ E ⎞⎛ 1 ⎞⎤ 3 T x= 2 f (x ) = (x ) exp⎢⎜ G ⎟⎜1− ⎟⎥ T1 ⎣⎝ kT1 ⎠⎝ x ⎠⎦ Using trial and error with a spreadsheet yields T = 4.27 K, 14.6 K, and 30.7 K to increase the saturation current by 2X, 10X, and 100X respectively. x f(x) Delta T 1.00000 1.00500 1.01000 1.01500 1.01400 1.01422 1.01922 1.02422 1.02922 1.03422 1.03922 1.04422 1.04922 1.04880 1.10000 1.10239 1.00000 1.27888 1.63167 2.07694 1.97945 2.00051 2.54151 3.22151 4.07433 5.14160 6.47438 8.13522 10.20058 10.00936 90.67434 100.0012 0.00000 1.50000 3.00000 4.50000 4.20000 4.26600 5.76600 7.26600 8.76600 10.26600 11.76600 13.26600 14.76600 14.64000 30.00000 30.71610 3.36 wd = wdo 1+ VR | (a) wd = 1μm 1+ φj 3.37 ( 5 10 = 2.69 μm (b) wd = 1μm 1+ = 3.67 μm 0.8 0.8 )( ) 1016 cm −3 1015 cm −3 N AND φ j = VT ln = (0.025V )ln = 0.633 V ni2 1020 cm−6 ( ) 2 11.7 ⋅ 8.854x10−14 F ⋅ cm−1 ⎛ ⎞ 2εs ⎛ 1 1 ⎞ 1 1 + wdo = ⎜ ⎟ φj = ⎜ 16 −3 + 15 −3 ⎟ (0.633V) −19 q ⎝ N A ND ⎠ 10 cm ⎠ 1.602x10 C ⎝10 cm wdo = 0.949 μm wd = 0.949μm 1+ 42 | wd = wdo 1+ VR φj 10V = 3.89 μm 0.633V | wd = 0.949μm 1+ 100V = 12.0 μm 0.633V 3.38 ( )( ) 1018 cm −3 1020 cm −3 N AND φ j = VT ln = (0.025V )ln = 1.04 V ni2 1020 cm−6 ( 2 11.7 ⋅ 8.854x10−14 F ⋅ cm−1 2εs ⎛ 1 1 ⎞ wdo = + ⎟ φj = ⎜ q ⎝ N A ND ⎠ 1.602x10−19 C | wd = 0.0368μm 1+ 5 = 0.0887 μm 1.04 3.39 Emax = 3x105 2(φ j + VR ) wd = 2(φ j + VR ) wdo 1+ VR = ⎞ 1 1 + ⎟ (1.04V) 18 −3 1020 cm−3 ⎠ ⎝ 10 cm VR wdo = 0.0368 μm wd = wdo 1+ )⎛⎜ φj | wd = 0.0368μm 1+ 25 = 0.184 μm 1.04 2φ j V 1+ R wdo φj φj 2(0.6V ) V V = −4 1+ R → VR = 374 V cm 10 cm 0.6 3.40 2(0.748V ) 2φ kV = 15.2 | E= j = −4 wdo 0.984x10 cm cm E w φ j + VR = max do = 2 φj 3x105 ( V 0.984x10−4 cm cm 2 0.748V ) VR = 291.3 − 0.748 = 291 V 3.41 VZ = 4 V; RZ = 0 Ω since the reverse breakdown slope is infinite. 3.42 Since NA >> ND, the depletion layer is all on the lightly-doped side of the junction. Also, VR >> φj, so φj can be neglected. Emax = qN A x p εS = qN A wd ( ) ( εS = qN A εS ( 2εS VR q NA ) 2 3x105 (11.7) 8.854x10−14 Emax εS NA = = = 2.91 x 1014 / cm3 −19 2qVR 2 1.602x10 1000 2 ) 43 3.43 φ j = VT ln N AND 10151020 = 0.025ln = 0.864V ni2 1020 ( ) 2(11.7) 8.854x10−14 ⎛ 1 2εS ⎛ 1 1 ⎞ 1 ⎞ −4 wdo = + + ⎟φ j = ⎜ ⎟0.864 = 1.057x10 cm ⎜ q ⎝ N A ND ⎠ 1.602x10−19 ⎝ 1015 1020 ⎠ C = " jo εS = wdo ( 11.7 8.854x10−14 1.057x10−4 ) = 9.80x10 -9 F / cm 2 | Cj = C "jo A 1+ 9.80x10-9 (0.05) = 5 1+ 0.864 VR φj = 188 pF 3.44 φ j = VT ln N AND 10181015 = 0.025ln = 0.748V ni2 1020 ( 2(11.7) 8.854x10−14 2εS ⎛ 1 1 ⎞ wdo = + ⎟φ j = ⎜ q ⎝ N A ND ⎠ 1.602x10−19 C = " jo εS wdo = ( 11.7 8.854x10−14 0.984x10−4 3.45 ( ) = 10.5x10 -9 (c) CD = ( 0.025V 3.46 ( ) ) = 100 pF (c) CD = 44 ( 0.025V | Cj = C "jo A ) ) = 0.04 μF = 10.5x10-9 (0.02) 10 1+ 0.748 VR φj ( ) (b) Q = I D τ T = 10−4 A 10−10 s = 10 fC ( ) | Q = I D τ T = 5x10−3 A 10−10 s = 0.50 pC −8 I D τ T 1A 10 s (a) CD = = = 0.400 μF VT 0.025V 100mA 10−8 s 1 ⎞ 1 0.748 = 0.984x10−4 cm + 18 15 ⎟ 10 10 ⎠ ⎝ 1+ −4 −10 I D τ T 10 A 10 s (a) CD = = = 400 fF VT 0.025V 25x10−3 A 10−10 s F / cm 2 )⎛⎜ ( ) (b) Q = I D τ T = 1A 10−8 s = 10.0 nC ( ) | Q = I D τ T = 100mA 10−8 s = 1.00 nC = 55.4 pF 3.47 N AND 10191017 = 0.025ln = 0.921V ni2 1020 φ j = VT ln ( ) 2(11.7) 8.854x10−14 ⎛ 1 2εS ⎛ 1 1 ⎞ 1 ⎞ wdo = + + ⎟φ j = ⎜ ⎟0.921 = 0.110 μm ⎜ q ⎝ N A ND ⎠ 1.602x10−19 ⎝ 1019 1017 ⎠ C jo = εS A wdo = ( )( ) = 9.42 pF / cm 11.7 8.854x10−14 10−4 −4 0.110x10 C jo | Cj = 2 1+ = VR φj 9.42 pF 5 1+ 0.921 = 3.72 pF 3.48 N AND 10191016 = 0.025ln = 0.864V ni2 1020 φ j = VT ln ( )⎛⎜ 11.7 8.854x10−14 0.25cm2 ) = 7750 pF 2(11.7) 8.854x10−14 2εS ⎛ 1 1 ⎞ wdo = + ⎟φ j = ⎜ q ⎝ N A ND ⎠ 1.602x10−19 C jo = εS A wdo = ( )( −4 0.334x10 1 ⎞ 1 + ⎟0.864 = 0.334μm ⎝ 1019 1016 ⎠ | Cj = C jo 1+ = VR φj 7750 pF 3 1+ 0.864 = 3670 pF 3.49 L= RFC C VDC C= C jo 1+ (b) C = (a) C = VR φj 39 pF 10V 1+ 0.75V 39 pF 1V 1+ 0.75V = 25.5 pF | f o = = 10.3 pF | f o = 10 μH 10 μH C 1 2π LC = 2π 1 2π LC ( 1 = ) 2π ( 1 ) 10−5 H 25.5 pF 10−5 H 10.3 pF = 9.97 MHz = 15.7 MHz 3.50 ⎛ ⎛ 50 A ⎞ 50 A ⎞ (a) VD = (0.025V )ln⎜1+ −7 ⎟ = 0.501 V | (b) VD = (0.025V )ln⎜1+ −15 ⎟ = 0.961 V ⎝ 10 A ⎠ ⎝ 10 A ⎠ 45 3.51 ⎛ 4x10−3 A ⎞ ⎛ 4x10−3 A ⎞ (a) VD = (0.025V )ln⎜1+ = 0.025V ln = 0.495 V | (b) V ⎟ ⎜ ( ) 1+ 10−14 A ⎟ = 0.668 V D 10−11 A ⎠ ⎝ ⎝ ⎠ 3.52 Rp = ρ p RS = R p + Rn Rn = ρ n Lp 0.025cm = (1Ω − cm) = 2.5Ω Ap 0.01cm 2 Ln 0.025cm = (0.01Ω − cm) = 0.025Ω An 0.01cm 2 RS = 2.53 Ω 3.53 ⎛ ⎛ I ⎞ 10−3 ⎞ (a) VD' = VT ln⎜1+ D ⎟ = (0.025V )ln⎜1+ = 0.708V −16 ⎟ ⎝ IS ⎠ ⎝ 5x10 ⎠ VD = VD' + I D RS = 0.708V + 10−3 A(10Ω)= 0.718 V (b) VD = VD' + I D RS = 0.708V + 10−3 A(100Ω)= 0.808 V 3.54 10Ω − μm2 ρ c = 10Ω − μm Ac = 1μm RC = = = 10Ω / contact Ac 1μm2 5 anode contacts and 14 cathode contacts 2 2 ρc 10Ω = 2Ω 5 10Ω = 0.71Ω Resistance of cathode contacts = 14 Resistance of anode contacts = 3.55 (a) From Fig. 3.21a, the diode is approximately 10.5 μm long x 8 μm wide. Area = 84 μm2. (b) Area = (10.5x0.13 μm) x (8x0.13μm) = 1.42 μm2. 46 3.56 (a) 5 = 10 4 I D + VD | VD = 0 I D = 0.500mA | I D = 0 VD = 5V 4.5V = 0.450 mA 10 4 Ω | VD = 0 I D = −2.00mA | I D = 0 VD = −6V Forward biased - VD = 0.5 V I D = (b) − 6 = 3000I D + VD −2V = −0.667 mA 3kΩ | VD = 0 I D = −1.00mA | I D = 0 VD = −3V In reverse breakdown - VD = −4 V I D = (c) − 3 = −3000I D + VD Reverse biased - VD = −3 V I D = 0 iD 2 mA 1 mA (a) Q-point (c) Q-point -6 -5 -4 -3 -2 vD -1 1 2 5 4 3 6 (b) Q-point -1 mA -2 mA 3.57 (a) 10 = 5000I D + VD | VD = 0 I D = 2.00 mA | VD = 5 V I D = 1.00 mA 9.5V = 1.90 mA 5kΩ | VD = 0 I D = −2.00 mA | VD = −5 V I D = −1.00 mA Forward biased - VD = 0.5V I D = (b) -10 = 5000I D + VD −6V = −1.20 mA 5kΩ | VD = 0 I D = −1.00 mA | I D = 0 VD = −2 V In reverse breakdown - VD = −4V I D = (c) − 2 = 2000I D + VD Reverse biased - VD = −2 V I D = 0 iD 2 mA (a) Q-point 1 mA (c) Q-point -6 -5 -4 -3 -2 v -1 1 (b) Q-point 2 3 4 5 D 6 -1 mA -2 mA 47 3.58 *Problem 3.58 - Diode Circuit V 1 0 DC 5 R 1 2 10K D1 2 0 DIODE1 .OP .MODEL DIODE1 D IS=1E-15 .END SPICE Results VD = 0.693 V ID = 0.431 μA 3.59 (a) −10 = 10 4 I D + VD | VD = 0 I D = −1.00 mA | VD = −5 V I D = −0.500 mA −10 − (−4)V = −0.600 mA 10kΩ | VD = 0 I D = 1.00 mA | VD = 5 V I D = 0.500 mA In reverse breakdown - VD = −4 V I D = (b) 10 = 10 4 I D + VD 10 − 0.5V = 0.950 mA 10kΩ | VD = 0 I D = −2.00 mA | I D = 0 Forward biased - VD = 0.5 V I D = (c) − 4 = 2000I D + VD Reverse biased - VD = −4 V I D = 0 iD 2 mA 1 mA (b) Q-point (c) Q-point -6 -5 -4 -3 -2 vD -1 1 (a) Q-point -1 mA -2 mA 48 2 3 4 5 6 VD = − 4 V iD (A) 0.002 0.001 -7 -6 -5 -4 -3 -2 v D (V) -1 1 2 3 4 5 6 7 -0.001 -0.002 49 3.60 R i D + v + V - D - The load line equation: V = iD R + vD We need two points to plot the load line. (a) V = 6 V and R = 4kΩ: For vD = 0, iD = 6V/4 kΩ = 1.5 mA and for iD = 0, vD = 6V. Plotting this line on the graph yields the Q-pt: (0.5 V, 1.4 mA). (b) V = -6 V and R = 3kΩ: For vD = 0, iD = -6V/3 kΩ = -2 mA and for iD = 0, vD = -6V. Plotting this line on the graph yields the Q-pt: (-4 V, -0.67 mA). (c) V = -3 V and R = 3kΩ: Two points: (0V, -1mA), (-3V, 0mA); Q-pt: (-3 V, 0 mA) (d) V = +12 V and R = 8kΩ: Two points: (0V, 1.5mA), (4V, 1mA); Q-pt: (0.5 V, 1.4 mA) (e) V = -25 V and R = 10kΩ: Two points: (0V, -2.5mA), (-5V, -2mA); Q-pt: (-4 V, -2.1 mA) i (A) D .002 Q-Point (0.5V,1.45 mA) (d) .001 Q-Point (-3V,0 mA) -7 -6 -5 -4 -3 Q-Point (0.5V,1.4 mA) -2 -1 1 (c) Q-Point (-4V,-0.67 mA) -.001 Load line for (b) -.002 Q-Point (-4V,-2.1 mA) 50 (e) 2 Load line for (a) 3 4 5 6 7 v (V) D 3.61 -9 Using the equations from Table 3.1, (f = 10-10 exp ..., etc.) VD = 0.7 V requires 12 iterations, VD = 0.5 V requires 22 iterations, VD = 0.2 V requires 384 iterations - very poor convergence because the second iteration (VD = 9.9988 V) is very bad. 3.62 Using Eqn. (3.28), ⎛i ⎞ V = iD R + VT ln⎜ D ⎟ ⎝ IS ⎠ ( ) or 10 = 10 4 iD + 0.025ln 1013 iD . ( 4 13 We want to find the zero of the function f = 10 −10 iD − 0.025ln 10 iD iD f .001 -0.576 .0001 8.48 .0009 0.427 .00094 0.0259 - converged ) 3.63 ⎛ I ⎞ 0.025 f = 10 −10 4 ID − 0.025ln⎜1+ D ⎟ | f ' = −10 4 − ID + IS ⎝ IS ⎠ x f(x) f'(x) 1.0000E+00 9.2766E-04 9.4258E-04 9.4258E-04 9.4258E-04 -9.991E+03 1.496E-01 3.199E-06 9.992E-16 9.992E-16 -1.000E+04 -1.003E+04 -1.003E+04 -1.003E+04 -1.003E+04 3.64 Create the following m-file: function fd=current(id) fd=10-1e4*id-0.025*log(1+id/1e-13); Then: fzero('current',1) yields ans = 9.4258e-04 + 1.0216e-21i 51 3.65 The one-volt source will forward bias the diode. Load line: 1 = 10 4 I D + VD | I D = 0 VD = 1V | VD = 0 I D = 0.1mA → (50 μA, 0.5 V ) [ ] −9 Mathematical model: f = 1−10 exp(40VD )−1 + VD → (49.9 μA, 0.501 V ) Ideal diode model: ID = 1V/10kΩ = 100μA; (100μA, 0 V) Constant voltage drop model: ID = (1-0.6)V/10kΩ = 40.0μA; (40.0μA, 0.6 V) 3.66 Using Thévenin equivalent circuits yields and then combining the sources I 1.2 k Ω 1.2 V - + V I 1k Ω - + + - - V 2.2 k Ω + + 1.5 V - 0.3 V (a) Ideal diode model: The 0.3 V source appears to be forward biasing the diode, so we will assume it is "on". Substituting the ideal diode model for the forward region yields 0.3V I= = 0.136 mA . This current is greater than zero, which is consistent with the diode 2.2kΩ being "on". Thus the Q-pt is (0 V, +0.136 mA). I - V V on - + + I 2.2 k Ω 0.6 V + - 2.2 k Ω + 0.3 V - 0.3 V CVD: Ideal Diode: (b) CVD model: The 0.3 V source appears to be forward biasing the diode so we will assume it 0.3V − 0.6V = −136 μA . is "on". Substituting the CVD model with Von = 0.6 V yields I = 2.2kΩ This current is negative which is not consistent with the assumption that the diode is "on". Thus the diode must be off. The resulting Q-pt is: (0 mA, -0.3 V). - V + I=0 2.2 k Ω + 52 0.3 V (c) The second estimate is more realistic. 0.3 V is not sufficient to forward bias the diode into -15 significant conduction. For example, let us assume that IS = 10 A, and assume that the full 0.3 V appears across the diode. Then ⎡ ⎛ 0.3V ⎞ ⎤ iD = 10−15 A⎢exp⎜ ⎟ −1⎥ = 163 pA , a very small current. ⎣ ⎝ 0.025V ⎠ ⎦ 3.67 The nominal values are: ⎛ R2 ⎞ ⎛ 2kΩ ⎞ VA = 3V ⎜ ⎟ = 3V ⎜ ⎟ = 1.20V ⎝ 2kΩ + 3kΩ ⎠ ⎝ R1 + R2 ⎠ and RTHA = 2kΩ(3kΩ) R1 R2 = = 1.20kΩ R1 + R2 2kΩ + 3kΩ ⎛ R4 ⎞ ⎛ 2kΩ ⎞ 2kΩ(2kΩ) R3 R4 VC = 3V ⎜ = = 1.00kΩ ⎟ = 3V ⎜ ⎟ = 1.50V and RTHC = R3 + R4 2kΩ + 2kΩ ⎝ 2kΩ + 2kΩ ⎠ ⎝ R3 + R4 ⎠ ⎛ 1.50 −1.20 ⎞ V I Dnom = ⎜ = 136 μA ⎟ ⎝1.20 + 1.00 ⎠ kΩ For maximum current, we make the Thévenin equivalent voltage at the diode anode as large as possible and that at the cathode as small as possible. VA = VC = 3V 3V = = 1.65V and R1 2kΩ(0.9) 1+ R2 1+ 2kΩ(1.1) 3V 3V = = 1.06V and R3 3kΩ(1.1) 1+ R4 1+ 2kΩ(0.9) RTHA = 2kΩ(0.9)2kΩ(1.1) R1 R2 = = 0.990kΩ R1 + R2 2kΩ(0.9)+ 2kΩ(1.1) RTHC = 3kΩ(1.1)2kΩ(0.9) R3 R4 = = 1.17kΩ R3 + R4 3kΩ(1.1)+ 2kΩ(0.9) ⎛ 1.65 −1.06 ⎞ V I Dmax = ⎜ = 274 μA ⎟ ⎝ 0.990 + 1.17 ⎠ kΩ For minimum current, we make the Thévenin equivalent voltage at the diode anode as small as possible and that at the cathode as large as possible. VA = VC = 3V 3V = = 1.350V and R1 2kΩ(1.1) 1+ R2 1+ 2kΩ(0.9) 3V 3V = = 1.347V and R3 3kΩ(0.9) 1+ R4 1+ 2kΩ(1.1) RTHA = 2kΩ(1.1)2kΩ(0.9) R1 R2 = = 0.990kΩ R1 + R2 2kΩ(1.1)+ 2kΩ(0.9) RTHC = 3kΩ(0.9)2kΩ(1.1) R3 R4 = = 1.21kΩ R3 + R4 3kΩ(0.9)+ 2kΩ(1.1) ⎛1.350 −1.347 ⎞ V = 1.39 μA ≅ 0 I Dmin = ⎜ ⎟ ⎝ 0.990 + 1.21 ⎠ kΩ 53 3.68 SPICE Input *Problem 3.68 V1 1 0 DC 4 R1 1 2 2K R2 2 0 2K R3 1 3 3K R4 3 0 2K D1 2 3 DIODE .MODEL DIODE D IS=1E-15 RS=0 .OP .END Results NAME D1 MODEL ID VD DIODE 1.09E-10 3.00E-01 The diode is essentially off - VD = 0.3 V and ID = 0.109 nA. This result agrees with the CVD model results. 3.69 (a) (a) Diode is forward biased :V = 3 − 0 = 3 V | I = 3 − (−7) = 0.625 mA 16kΩ 5 − (−5) = 0.625 mA (b) Diode is forward biased :V = −5 + 0 = −5 V | I = 16kΩ (c) Diode is reverse biased : I = 0 | V = −5 + 16kΩ(I )= −5 V | VD = −10 V (d ) Diode is reverse biased : I = 0 | V = 7 −16kΩ(I ) = 7 V | VD = −10 V (b) (a) Diode is forward biased :V = 3 − 0.7 = 2.3 V | I = 2.3 − (−7) = 0.581 mA 16kΩ 5 − (−4.3) (b) Diode is forward biased :V = −5 + 0.7 = −4.3 V | I = = 0.581 mA 16kΩ (c) Diode is reverse biased : I = 0 | V = −5 + 16kΩ(I )= −5 V | VD = −10 V (d ) Diode is reverse biased : I = 0 | V = 7 −16kΩ(I ) = 7 V | VD = −10 V 3.70 (a) 3 − (−7) = 100 μA 100kΩ 5 − (−5) (b) Diode is forward biased :V = −5 + 0 = −5 V | I = = 100 μA 100kΩ (c) Diode is reverse biased : I = 0 A | V = −5 + 100kΩ(I )= −5 V | VD = −10 V (a) Diode is forward biased :V = 3 − 0 = 3 V | I = (d ) Diode is reverse biased : I = 0 A | V = 7 −100kΩ(I )= 7 V | VD = −10 V (b) 54 2.4 − (−7) = 94.0 μA 100kΩ 5 − (−4.4) (b) Diode is forward biased :V = −5 + 0.6 = −4.4 V | I = = 94.0 μA 100kΩ (c) Diode is reverse biased : I = 0 | V = −5 + 100kΩ(I ) = −5 V | VD = −10 V (a) Diode is forward biased :V = 3 − 0.6 = 2.4 V | I = (d ) Diode is reverse biased : I = 0 | V = 7 −100kΩ(I ) = 7 V | VD = −10 V 3.71 (a) (a) D1 on, D2 on : I D2 = D1 : (409 μA, 0 V ) 0 − (−9) = 409μA | I D1 = 409μA − 22kΩ D2 : (270 μA, 0 V ) 6−0 = 270μA 43kΩ 6−0 = 140 μA | VD2 = −9 − 0 = −9V 43kΩ D2 : (0 A, − 9 V ) (b) D1 on, D2 off : I D2 = 0 | I D1 = D1 : (140 μA, 0 V ) (c) D1 off, D2 on : I D1 = 0 | I D2 = D1 : (0 A,−3.92 V ) 65kΩ D2 : (230 μA,0 V ) (d ) D1 on, D2 on : I D 2 = D1 : (140 μA,0 V ) 6 − (−9) 0 − (−6) = 230 μA | VD1 = 6 − 43x103 I D2 = −3.92 V = 140 μA | I D1 = 43kΩ D2 : (270 μA,0 V ) 9−0 −140 μA = 270 μA 22kΩ (b) (a) D1 on, D2 on : I D2 = -0.75 − 0.75 − (−9) = 341μA | I D1 = 341μA − 22kΩ D1 : (184 μA, 0.75 V) D2 : (341 μA, 0.75 V) 6 − (−0.75) 43kΩ = 184μA (b) D1 on, D2 off : 6 − 0.75 = 122μA | VD 2 = −9 − 0.75 = −9.75V 43kΩ D1 : (122 μA, 0.75 V) D2 : (0 A, − 9.75 V) I D2 = 0 | I D1 = 55 (c) D1 off, D2 on : I D1 = 0 | I D2 = 6 − 0.75 − (−9) = 219μA | VD1 = 6 − 43x103 I D2 = −3.43V 65kΩ D1 : (0 A, − 3.43 V ) D2 : (219 μA, 0.75 V ) (d) D1 on, D2 on : I D2 = 0.75 − 0.75 − (−6) 43kΩ D1 : (235 μA, 0.75 V) 9 − 0.75 − 400μA = 235μA 22kΩ D2 : (140 μA, 0.75 V) = 140μA | I D1 = 3.72 (a) (a) D1 and D2 forward biased I D2 = 0 − (−9) V = 600μA 15 kΩ D1 : (0 V, 200 μA) I D1 = I D2 − D2 : (0 V, 600 μA) 6 − (0) V = 200μA 15 kΩ (b) D1 forward biased, D2 reverse biased 6−0 V = 400μA VD2 = −9 − 0 = −9 V 15 kΩ D1 : (0 V, 400 μA) D2 : (-9 V, 0 A ) I D1 = (c) D1 reverse biased, D2 forward biased 6V − (−9V ) = 500μA VD1 = 6 −15000I D2 = −1.50V 30kΩ D1 : (−1.50 V, 0 A) D2 : (0 V, 500 μA) I D2 = (d) D1 and D2 forward biased I D2 = 0 − (−6) V = 400μA 15 kΩ D1 : (0 V, 200 μA) I D1 = 9 − (0) V 15 kΩ D2 : (0 V, 400 μA) − I D2 = 200μA (b) (a) D1 on, D2 on : I D2 = -0.75 − 0.75 − (−9) = 500μA | I D1 = 500μA − 15kΩ D1 : (50.0 μA, 0.75 V) D2 : (500 μA, 0.75 V) 56 6 − (−0.75) 15kΩ = 50.0μA (b) D1 on, D2 off : 6 − 0.75 = 350μA | VD2 = −9 − 0.75 = −9.75V 15kΩ D1 : (350 μA, 0.75 V) D2 : (0 A, − 9.75 V) I D2 = 0 | I D1 = (c) D1 off, D2 on : 6 − 0.75 − (−9) = 475μA | VD1 = 6 −15x103 I D2 = −1.13V 30kΩ D1 : (0 A, −1.13 V ) D2 : (475 μA, 0.75 V ) I D1 = 0 | I D2 = (d) D1 on, D2 on : I D2 = 0.75 − 0.75 − (−6) 15kΩ D1 : (150 μA, 0.75 V) 9 − 0.75 − 400μA = 150μA 15kΩ D2 : (400 μA, 0.75 V) = 400μA | I D1 = 3.73 Diodes are labeled from left to right (a) D1 on, D2 off, D3 on : I D2 = 0 | I D1 = 0 − (−5) 10 − 0 = 0.990mA 3.3kΩ + 6.8kΩ → I D3 = 1.09mA | VD2 = 5 − (10 − 3300I D1 ) = −1.73V 2.4kΩ D1 : (0.990 mA, 0 V) D2 : (0 mA, −1.73 V) D3 : (1.09 mA, 0 V) I D3 + 0.990mA = (b) D1 on, D2 off, D3 on : I D2 = 0 | I D3 = 0 (10 − 0)V = 0.495mA | VD2 = 5 − (10 − 8200I D1 )= −0.941V 8.2kΩ + 12kΩ 0 − (−5V ) − I D1 = 0.005mA I D3 = 10kΩ D1 : (0.495 mA, 0 V ) D2 : (0 A, − 0.941 V ) D3 : (0.005 mA, 0 V ) I D1 = 57 (c) D1 on, D2 on, D3 on 0 − (−10) 0 − (2) V = 1.22mA > 0 | I12K = V = −0.167mA | I D2 = I D1 + I12K = 1.05mA > 0 8.2kΩ 12kΩ 2 − (−5) V = 0.700mA | I D3 = I10K − I12K = 0.533mA > 0 I10K = 10kΩ D1 : (1.22 mA, 0 V ) D2 : (1.05 mA, 0 V ) D3 : (0.533 mA, 0 V ) I D1 = (d) D1 off, D2 off, D3 on : I D1 = 0, I D2 = 0 12 − (−5) V = 1.21mA > 0 | VD1 = 0 − (−5 + 4700I D3 ) = −0.667V < 0 4.7 + 4.7 + 4.7 kΩ VD2 = 5 − (12 − 4700I D3 ) = −1.33V < 0 I D3 = D1 : (0 A, − 0.667 V ) D2 : (0 A, −1.33 V ) D3 : (1.21 mA, 0 V ) 3.74 Diodes are labeled from left to right (a) D1 on, D2 off, D3 on : I D2 = 0 | I D1 = −0.6 − (−5) 10 − 0.6 − (−0.6) 3.3kΩ + 6.8kΩ = 0.990mA → I D3 = 0.843mA | VD2 = 5 − (10 − 0.6 − 3300I D1 )= −1.13V 2.4kΩ D1 : (0.990 mA, 0.600 V) D2 : (0 A, −1.13 V) D3 : (0.843 mA, 0.600V) I D3 + 0.990mA = (b) D1 on, D2 off, D3 off : I D2 = 0 | I D3 = 0 10 − 0.6 − (−5) V = 0.477mA | VD2 = 5 − (10 − 0.6 − 8200I D1 )= −0.490V 8.2kΩ + 12kΩ + 10kΩ VD3 = 0 − (−5 + 10000I D1 )= +0.230V < 0.6V so the diode is off I D1 = D1 : (0.477 mA, 0.600 V) D2 : (0 A, − 0.490 V) D3 : (0 A, 0.230 V) (c) D1 on, D2 on, D3 on I D1 = −0.6 − (−9.4) V 8.2 kΩ = 1.07mA > 0 | I12K = 58 12 kΩ = −0.167mA 1.4 − (−5) V = 0.640mA | I D3 = I10K − I12K = 0.807mA > 0 kΩ 10 D2 : (0.906 mA, 0.600 V) D3 : (0.807 mA, 0.600 V) I D2 = I D1 + I12K = 0.906mA > 0 | I10K = D1 : (1.07 mA, 0.600 V) −0.6 − (1.4) V (d) D1 off, D2 off, D3 on : I D1 = 0, I D2 = 0 11.4 − (−5) V = 1.16mA > 0 | VD1 = 0 − (−5 + 4700I D3 ) = −0.452V < 0 4.7 + 4.7 + 4.7 kΩ VD2 = 5 − (11.4 − 4700I D3 ) = −0.948V < 0 I D3 = D1 : (0 A, − 0.452 V ) D2 : (0 A, − 0.948 V ) D3 : (1.16 mA, 0.600 V ) 3.75 *Problem 3.75(a) (Similar circuits are used for the other three cases.) V1 1 0 DC 10 V2 4 0 DC 5 V3 6 0 DC -5 R1 2 3 3.3K R2 3 5 6.8K R3 5 6 2.4K D1 1 2 DIODE D2 4 3 DIODE D3 0 5 DIODE .MODEL DIODE D IS=1E-15 RS=0 .OP .END NAME D1 D2 D3 MODEL DIODE DIODE DIODE ID 9.90E-04 -1.92E-12 7.98E-04 VD 7.14E-01 -1.02E+00 7.09E-01 NAME D1 D2 MODEL DIODE DIODE ID 4.74E-04 -4.22E-13 VD 6.95E-01 -4.21E-01 NAME D1 MODEL DIODE ID 8.79E-03 VD 7.11E-01 D3 DIODE 2.67E-11 2.63E-01 D2 D3 DIODE DIODE 1.05E-03 7.96E-04 7.16E-01 7.09E-01 NAME D1 D2 D3 MODEL DIODE DIODE DIODE ID -4.28E-13 -8.55E-13 1.15E-03 VD -4.27E-01 -8.54E-01 7.18E-01 For all cases, the results are very similar to the hand analysis. 3.76 59 I D1 = 10 − (−20) = 1.50mA | I D2 = 0 10kΩ + 10kΩ 0 − (−10) I D3 = = 1.00mA | VD2 = 10 −10 4 I D1 − 0 = −5.00V 10kΩ D1 : (1.50 mA, 0 V) D2 : (0 A,−5.00 V) D3 : (1.00 mA, 0 V) 3.77 *Problem 3.77 V1 1 0 DC -20 V2 4 0 DC 10 V3 6 0 DC -10 R1 1 2 10K R2 4 3 10K R3 5 6 10K D1 3 2 DIODE D2 3 5 DIODE D3 0 5 DIODE .MODEL DIODE D IS=1E-14 RS=0 .OP .END NAME D1 D2 D3 MODEL DIODE DIODE DIODE ID 1.47E-03 -4.02E-12 9.35E-04 VD 6.65E-01 -4.01E+00 6.53E-01 The simulation results are very close to those given in Ex. 3.8. 3.78 3.9kΩ = 6.28V | RTH = 11kΩ 3.9kΩ = 2.88kΩ 3.9kΩ + 11kΩ 6.28 − 4 IZ = = 0.792mA > 0 | (I Z ,VZ )= (0.792 mA,4 V ) 2.88kΩ VTH = 24V 60 3.79 −6.28 = 2880I D + VD | I D = 0,VD = −6.28V | VD = 0, I D = -6 -5 -4 -3 -2 -1 v Q-point −6.28 = −2.18mA 2880 D -1 mA -2 mA i 3.80 IS = 3.81 IS = D Q-Point: (-0.8 mA, -4 V) 27 − 9 9V = 1.20mA → I L < 1.20 mA | RL > = 7.50 kΩ 15kΩ 1.2mA 27 − 9 = 1.20mA | P = (9V )(1.20mA) = 10.8 mW 15kΩ 3.82 ⎛ 1 VS − VZ VZ VS 1⎞ − = − VZ ⎜ + ⎟ | PZ = VZ I Z RS RL RS ⎝ RS RL ⎠ ⎛ 1 30V 1 ⎞ nom I Znom = − 9V ⎜ + ⎟ = 0.500 mA | PZ = 9V (0.500mA)= 4.5 mW 15kΩ 15kΩ 10kΩ ⎝ ⎠ ⎞ ⎛ 30V (1.05) 1 1 ⎟ = 0.796 mA I Zmax = − 9V (0.95)⎜⎜ + ⎟ 10kΩ(1.05) 15kΩ(0.95) 15kΩ 0.95 ( ) ⎠ ⎝ IZ = PZmax = 9V (.95)(0.796mA)= 6.81 mW I min Z 30V (0.95) ⎞ ⎛ 1 1 ⎟ = 0.215 mA ⎜ = − 9V (1.05)⎜ + ⎟ 10kΩ(0.95) 15kΩ(1.05) 15kΩ 1.05 ( ) ⎠ ⎝ PZmin = 9V (1.05)(0.215mA)= 2.03 mW 3.83 100Ω 24 −15 = 24.0V | RTH = 150Ω 100Ω = 60Ω | I Z = = 150 mA 150Ω + 100Ω 60 60 −15 = 300 mA | P = 15I Z = 4.50 W P = 15I Z = 2.25 W | (b) I Z = 150 (a) VTH = 60V 61 3.84 IZ = ⎛ 1 VS − VZ VZ VS 1⎞ − = − VZ ⎜ + ⎟ RS RL RS ⎝ RS RL ⎠ PZ = VZ I Z (60 −15)V − 15V = 150 mA | PZnom = 15V (150mA) = 2.25 W 150Ω 100Ω ⎛ ⎞ 60V (1.1) 1 1 ⎟ = 266 mA = −15V (0.90)⎜⎜ + ⎟ 100Ω(1.1) 150Ω 0.90 150Ω(0.90) ( ) ⎝ ⎠ I Znom = I Zmax | PZmax = 15V (0.90)(266mA)= 3.59 W I Zmin = 60V (0.90) ⎛ ⎞ 1 1 ⎟ = 43.9 mA −15V (1.1)⎜⎜ + ⎟ 100Ω(0.9) 150Ω 1.1 150Ω(1.1) ( ) ⎝ ⎠ PZmin = 15V (1.1)(43.9mA)= 0.724 W 3.85 Using MATLAB, create the following m-file with f = 60 Hz: function f=ctime(t) f=5*exp(-10*t)-6*cos(2*pi*60*t)+1; Then: fzero('ctime',1/60) yields ans = 0.01536129698461 and T = (1/60)-0.0153613 = 1.305 ms. ΔT = 1 120π ΔT = 1 120π 3.86 IT 5 2Vr | Vr = = = 0.8333V VP C 0.1(60) 2(0.8333) 6 = 1.40 ms ⎛ I ⎞ ⎛ 48.6 A ⎞ VD = nVT ln⎜1+ D ⎟ = 2(0.025V )ln⎜1+ −9 ⎟ = 1.230 V ⎝ 10 A ⎠ ⎝ IS ⎠ 62 3.87 ⎛ I ⎞ Von = nVT ln⎜1+ D ⎟ | VD = Von + I D RS ⎝ IS ⎠ ⎛ 100 A ⎞ VD = 1.6(0.025V )ln⎜1+ −8 ⎟ + 100 A(0.01Ω) = 1.92 V ⎝ 10 A ⎠ ⎛100 A ⎞⎛ 1ms ⎞ I ΔT = 0.92V ⎜ Pjunction ≅ Von I DC = Von P ⎟⎜ ⎟ = 2.75 W 2T ⎝ 2 ⎠⎝16.7ms ⎠ 2 4⎛ T ⎞ 2 4 ⎛16.7ms ⎞ PR ≅ ⎜ ⎟ I DC RS = ⎜ ⎟(3A) 0.01Ω = 2.00 W 3 ⎝ ΔT ⎠ 3 ⎝ 1ms ⎠ Ptotal = 4.76 W 3.88 VDC = 1 T 1⎡ T ∫ v (t )dt = T ⎢⎣(V P − Von )T − 0 VDC = 0.975(18V )= 17.6 V 0.05(VP − Von )⎤ TVr ⎤ ⎡ ⎥ = 0.975(VP − Von ) ⎥ = ⎢(VP − Von )− 2 ⎦ ⎢⎣ 2 ⎥⎦ 3.89 1 PD = T 2 1 ΔT 2 ⎛ t ⎞ ∫ i (t )RS dt = T ∫ I P ⎜⎝1− ΔT ⎟⎠ RS dt 0 0 T 2 D ΔT 2 ⎛ 2t t2 ⎞ I P2 RS ⎛ t2 t3 ⎞ 1− + dt = t − + ⎟ ⎟ ⎜ ⎜ ∫ ΔT ΔT 2 T ⎝ ΔT 3ΔT 2 ⎠ ⎠ 0 ⎝ 0 2 I R ⎛ ΔT ⎞ 1 2 ⎛ ΔT ⎞ PD = P S ⎜ΔT − ΔT + ⎟ = I P RS ⎜ ⎟ T ⎝ 3 ⎠ 3 ⎝ T ⎠ I2R PD = P S T ΔT 3.90 Using SPICE with VP = 10 V. 15V Voltage 10V 5V 0V -5V -10V t -15V 0s 10ms 20ms 30ms 40ms 50ms 63 3.91 ( ) (a) Vdc = −(VP − Von ) = − 6.3 2 −1 = −7.91V (c) PIV ≥ 2VP = 2 ⋅ 6.3 2 = 17.8V (e) ΔT = (b) C = I T 7.91 1 1 = = 1.05F Vr 0.55 0.5 60 ( ) (d) I surge = ωCVP = 2π (60)(1.05) 6.3 2 = 3530 A 2(.25) 2Vr 2T 7.91 2 1 1 = = 0.628ms | I P = I dc = = 841A ΔT .5 60 .628ms ω VP 2π (60) 6.3 2 1 3.92 ( ) VOnom = −(VP − Von )= − 6.3 2 −1 = −7.91V ( = −(V ) [ ] )= −[6.3(0.9) 2 −1]= −7.02V VOmax = − VPmax − Von = − 6.3(1.1) 2 −1 = −8.80V VOmin min P − Von Circuit3_93b-Transient-8 3.93 *Problem 3.93 VS 1 0 DC 0 AC 0 SIN(0 10 60) D1 2 1 DIODE R 2 0 0.25 C 2 0 0.5 .MODEL DIODE D IS=1E-10 RS=0 .OPTIONS RELTOL=1E-6 .TRAN 1US 80MS .PRINT TRAN V(1) V(2) I(VS) .PROBE V(1) V(2) I(VS) .END +0.000e+000 +10.000m +20.000m +30.000m I P = I dc 64 9 2 1 2T = = 923A ΔT 0.25 60 1.3ms Time (s) +50.000m +10.000 +5.000 +0.000e+000 -5.000 -10.000 V(2) *REAL(Rectifier)* SPICE Graph Results: VDC = 9.29 V, Vr = 1.05 V, IP = 811 A, ISC = 1860 A I T 9.00V 1 1 Vdc = −(VP − Von ) = −(10 −1)= −9.00V | Vr = = = 1.20V C 0.25Ω 60s 0.5F I SC = ωCVP = 2π (60)(0.5)(10)= 1890 A | ΔT = +40.000m 2(1.2) 1 2Vr = = 1.30ms ω VP 2π (60) 10 1 +60.000m +70.000m Circuit3_93b-Transient-11 (Amp) +0.000e+000 +20.000m +40.000m +60.000m +80.000m Time (s) +100.000m +120.000m +140.000m +10.000 +5.000 +0.000e+000 -5.000 -10.000 V(1) V(2) *REAL(Rectifier)* SPICE Graph Results: VDC = -6.55 V, Vr = 0.58 V, IP = 150 A, ISC = 370 A Note that a significant difference is caused by the diode series resistance. 3.94 ( ) (a) Vdc = −(VP − Von )= − 6.3 2 −1 = −7.91V ( ) 2(.25) 2Vr 2T 7.91 2 1 1 = = 94.3μs | I P = I dc = = 839 A ΔT ω VP 2π (400) 6.3 2 .5 400 94.3μs 1 3.95 ( ) (a) Vdc = −(VP − Von )= − 6.3 2 −1 = −7.91V (c) PIV ≥ 2VP = 2 ⋅ 6.3 2 = 17.8V (e) ΔT = I T 7.91 1 1 = = 0.158F Vr 0.25 0.5 400 (d ) I surge = ωCVP = 2π (400)(0.158) 6.3 2 = 3540 A (c) PIV ≥ 2VP = 2 ⋅ 6.3 2 = 17.8V (e) ΔT = (b) C = 1 2Vr = ω VP 2π 105 1 ( ) I T 7.91 1 1 = = 633μF Vr 0.25 0.5 105 ( ) ( ) (d ) I surge = ωCVP = 2π 105 (633μF ) 6.3 2 = 3540 A 2(.25) 6.3 2 (b) C = = 0.377μs | I P = I dc 2T 7.91 2 1 = = 839 A 5 .5 10 0.377μs ΔT 3.96 65 (a) C = 1 IT 1 = = 556 μF Vr 3000(0.01) 60 3000 (c) Vrms = = 2120 V (d ) ΔT = 2 ⎞ 2T ⎛ 2 ⎞⎛ 1 = 1⎜ ⎟⎜ I P = I dc ⎟ = 88.9 A ΔT ⎝ 60 ⎠⎝ 0.375ms ⎠ (b) PIV ≥ 2VP = 2 ⋅ 3000 = 6000V 1 1 2Vr = 2(0.01) = 0.375ms ω VP 2π (60) (e) I surge = ωCVP = 2π (60)(556μF )(3000)= 629 A 3.97 Assuming Von = 1 V: V − Von 1 1 ⎛ 1 ⎞⎛ 30 ⎞ 3.3 + 1 C= P T = = 3.04 V ⎜ ⎟⎜ ⎟ = 6.06 F | PIV = 2VP = 2(3.3 + 1)V = 8.6 V | Vrms = Vr R 0.025 ⎝ 60 ⎠⎝ 3.3⎠ 2 ΔT = 1 ω I P = I dc ⎛ 1 ⎞⎛ 3.3V ⎞ 1 2T VP − Von 2 = ⎜ s⎟⎜ ⎟ = 0.520 ms RC VP 2π (60) 0.110Ω(6.06F )⎝ 60 ⎠⎝ 4.3V ⎠ ⎛ 2 ⎞⎛ ⎞ 1 2T = 30⎜ s ⎟⎜ ⎟ = 1920 A | I surge = ωCVP = 2π (60 / s)(6.06F )(4.3V ) = 9820 A ΔT ⎝ 60 ⎠⎝ 0.520ms ⎠ 3.98 40V vO 20V v1 0V vS Time -20V 0s 5ms 10ms 15ms 20ms 3.99 *Problem 3.99 VS 2 1 DC 0 AC 0 SIN(0 1500 60) D1 2 3 DIODE D2 0 2 DIODE C1 1 0 500U C2 3 1 500U RL 3 0 3K .MODEL DIODE D IS=1E-15 RS=0 .OPTIONS RELTOL=1E-6 .TRAN 0.1MS 100MS .PRINT TRAN V(2,1) V(3) I(VS) 66 25ms 30ms VDC = 2(VP - Von) = 2(17 - 1) = 32 V. .PROBE V(3) V(2,1) I(VS) .END 4.0kV 3.0kV vO 2.0kV 1.0kV vS 0V -1.0kV Time -2.0kV 0s 20ms 40ms 60ms 80ms 100ms Simulation Results: VDC = 2981 V, Vr = 63 V The doubler circuit is effectively two half-wave rectifiers connected in series. Each capacitor is discharged by I = 3000V/3000 = 1 A for 1/60 second. The ripple voltage on each capacitor is 33.3 V. With two capacitors in series, the output ripple should be 66.6 V, which is close to the simulation result. 3.100 ( ) (a) Vdc = −(VP − Von ) = − 15 2 −1 = −20.2 V (b) C = (c) PIV ≥ 2VP = 2 ⋅15 2 = 42.4 V (e) ΔT = ( ) (d ) I surge = ωCVP = 2π (60)(1.35) 15 2 = 10800 A 2(.25) 1 20.2V ⎛ 1 ⎞ 1 2Vr T = = 0.407 ms | I P = I dc = = 1650 A ⎜ s⎟ ω VP 2π (60) 15 2 ΔT 0.5Ω ⎝ 60 ⎠ 0.407ms 1 3.101 ( ) (a) Vdc = −(VP − Von )= − 9 2 −1 = −11.7 V (b) C = (c) PIV ≥ 2VP = 2 ⋅ 9 2 = 25.5 V (e) ΔT = I ⎛ T ⎞ 20.2V ⎛ 1 ⎞⎛ 1 ⎞ ⎜ ⎟= ⎜ ⎟⎜ ⎟ = 1.35 F Vr ⎝ 2 ⎠ 0.5Ω ⎝ 0.25V ⎠⎝120s ⎠ I ⎛ T ⎞ 11.7V ⎛ 1 ⎞⎛ 1 ⎞ ⎜ ⎟= ⎜ ⎟⎜ ⎟ = 0.780 F Vr ⎝ 2 ⎠ 0.5Ω ⎝ 0.25V ⎠⎝120s ⎠ ( ) (d ) I surge = ωCVP = 2π (60)(0.780) 9 2 = 3740 A ⎞ 2(.25) 1 1 2Vr T 11.7V ⎛ 1 ⎞⎛ = = 0.526 ms | I P = I dc = ⎜ s⎟⎜ ⎟ = 958 A ω VP 2π (60) 9 2 ΔT 0.5Ω ⎝ 60 ⎠⎝ 0.407ms ⎠ 1 67 3.102 *Problem 3.102 VS1 1 0 DC 0 AC 0 SIN(0 14.14 400) VS2 0 2 DC 0 AC 0 SIN(0 14.14 400) D1 3 1 DIODE D2 3 2 DIODE C 3 0 22000U R303 .MODEL DIODE D IS=1E-10 RS=0 .OPTIONS RELTOL=1E-6 .TRAN 1US 5MS .PRINT TRAN V(1) V(2) V(3) I(VS1) .PROBE V(1) V(2) V(3) I(VS1) .END 20V 10V vS 0V -10V vO Time -20V 0s 1.0ms 2.0ms 3.0ms 4.0ms Simulation Results: VDC = -13.4 V, Vr = 0.23 V, IP = 108 A VDC = VP − Von = 10 2 − 0.7 = 13.4 V | Vr = ΔT = 1 120π I P = I dc 2Vr 1 = VP 120π 2(0.254) 14.1 1 13.4 1 = 0.254 V 3 800 22000μF = 0.504 ms 1 T 13.4V 1 = s = 150 A 3Ω 60 0.504 ms ΔT Simulation with RS = 0.02 Ω. Circuit3_102-Transient-15 +0.000e+000 +2.000m +4.000m +6.000m +8.000m Time (s) +10.000m +12.000m +14.000m +15.000 +10.000 +5.000 +0.000e+000 -5.000 -10.000 -15.000 V(1) V(2) *REAL(Rectifier)* Simulation Results: VDC = -12.9 V, Vr = 0.20 V, IP = 33.3 A, ISC = 362 A. RS results in a significant reduction in the values of IP and ISC. 68 5.0ms 3.103 (a) C = 1 ⎛ 1s ⎞⎛ 30 A ⎞ VP − Von 1 T = ⎜ ⎟⎜ ⎟ = 3.03 F (b) PIV = 2VP = 2(3.3 + 1)V = 8.6 V R 0.025 ⎝120 ⎠⎝ 3.3V ⎠ Vr 3.3 + 1 (c) Vrms = 2 (e) I P = I dc = 3.04 V 2(0.025)(3.3) 2Vr 1 = = 0.520 ms ω VP 2π (60) 4.3 1 (d) ΔT = ⎞ ⎛ 1 ⎞⎛ T 1 = 30 A⎜ s ⎟⎜ ⎟ = 962 A | I surge = ωCVP = 2π (60 / s)(3.03F )(4.3V )= 4910 A ΔT ⎝ 60 ⎠⎝ 0.520ms ⎠ 3.104 (a) C = I T 1 1 = = 139 μF Vr 2 3000(0.01) 2 ⋅120 (c) VS = I P = I dc 3000 2 = 2120 V (d ) ΔT = 1 2 ω ⎛ 1 ⎞⎛ ⎞ 1 T = 1⎜ s ⎟⎜ ⎟ = 44.4 A ΔT ⎝ 60 ⎠⎝ 0.375ms ⎠ (b) PIV ≥ 2VP = 6000 V Vr 1 = 2(0.01) = 0.375 ms VP 2π (60) (e) I surge = ωCVP = 2π (60 / s)(139μF )(3000V )= 157 A 3.105 The circuit is behaving like a half-wave rectifier. The capacitor should charge during the first 1/2 cycle, but it is not. Therefore, diode D1 is not functioning properly. It behaves as an open circuit. 3.106 ( ) (a) Vdc = −(VP − 2Von )= − 15 2 − 2 = −19.2 V (b) C = (c) PIV ≥ VP = 15 2 = 21.2 V ( ) (d ) I surge = ωCVP = 2π (60 / s)(1.28F ) 15 2 = 10200 A ⎞ 2(.25) 1 2Vr T 19.2V ⎛ 1s ⎞⎛ 1 = = 0.407 ms | I P = I dc = ⎜ ⎟⎜ ⎟ = 1570 A ω VP 2π (60) 15 2 ΔT 0.5Ω ⎝ 60 ⎠⎝ 0.407ms ⎠ 1 (e) ΔT = 3.107 (a) C = (c) VS = I P = I dc I ⎛ T ⎞ 19.2V ⎛ 1 ⎞⎛ 1 ⎞ s⎟ = 1.28 F ⎜ ⎟= ⎜ ⎟⎜ Vr ⎝ 2 ⎠ 0.5Ω ⎝ 0.25V ⎠⎝ 120 ⎠ ⎛ 1 ⎞ I ⎛T ⎞ 1A s⎟ = 278 μF ⎜ ⎟= ⎜ Vr ⎝ 2 ⎠ 3000V (0.01)⎝ 120 ⎠ 3000 2 = 2120 V (d ) ΔT = (b) PIV ≥ VP = 3000 V 1 1 2Vr = 2(0.01) = 0.375 ms ω VP 2π (60) ⎛1 ⎞ 1 T = 1A⎜ s⎟ = 44.4 A ΔT ⎝ 60 ⎠ 0.375ms (e) I surge = ωCVP = 2π (60)(278μF )(3000) = 314 A 69 3.108 (a) C = ⎛ 1 ⎞ I ⎛T ⎞ 30 A s⎟ = 3.03 F ⎜ ⎟= ⎜ Vr ⎝ 2 ⎠ (0.025)(3.3V )⎝ 120 ⎠ (c) Vrms = I P = I dc 5.3 2 = 3.75 V (d ) ΔT = ⎡ 0.025(3.3)⎤ 1 2Vr ⎥ = 0.468 ms = 2⎢ ω VP 2π (60) ⎢⎣ 5.3 ⎥⎦ 1 ⎛1 ⎞ T 1 = 30 A⎜ s⎟ = 1070 A ΔT ⎝ 60 ⎠ 0.468ms 3.109 V1 = VP - Von = 49.3 V and (e) I surge = ωCVP = 2π (60 / s)(3.03F )(3.3V )= 3770 A V2 = -(VP -Von) = -49.3V. 3.110 *Problem 3.110 VS1 1 0 DC 0 AC 0 SIN(0 35 60) VS2 0 2 DC 0 AC 0 SIN(0 35 60) D1 1 3 DIODE D4 2 3 DIODE D2 4 1 DIODE D3 4 2 DIODE C1 3 0 0.1 C2 4 0 0.1 R1 3 0 500 R2 4 0 500 .MODEL DIODE D IS=1E-10 RS=0 .OPTIONS RELTOL=1E-6 .TRAN 10US 50MS .PRINT TRAN V(3) V(4) .PROBE V(3) V(4) .END 3.111 ( ) (a) Vdc = −(VP − 2Von )= − 15 2 − 2 = −19.2 V (c) PIV ≥ VP = 15 2 = 21.2 V (e) ΔT = 70 (b) PIV ≥ Vdc + 2Von = (3.3 + 2) = 5.3 V 40V v1 20V 0V -20V v2 Time -40V 0s (b) C = 10ms 20ms 30ms 40ms 50ms I ⎛ T ⎞ 19.2V ⎛ 1 ⎞⎛ 1 ⎞ ⎜ ⎟= ⎜ ⎟⎜ ⎟ = 1.28 F Vr ⎝ 2 ⎠ 0.5Ω ⎝ 0.25⎠⎝120 ⎠ ( ) (d ) I surge = ωCVP = 2π (60 / s)(1.28F ) 15V 2 = 10200 A ⎞ 2(.25) 1 2Vr T 19.2V ⎛ 1 ⎞⎛ 1 = = 0.407 ms | I P = I dc = ⎜ s ⎟⎜ ⎟ = 1570 A ΔT 0.5Ω ⎝ 60 ⎠⎝ 0.407ms ⎠ ω VP 2π (60) 15 2 1 3.112 3.3-V, 15-A power supply with Vr ≤ 10 mV. Assume Von = 1 V. Rectifier Type Half Wave Full Wave Full Wave Bridge Peak Current 533 A 266 A 266 A PIV 8.6 V 8. 6 V 5.3 V Filter Capacitor 25 F 12.5 F 12.5 F (i) The large value of C suggests we avoid the half-wave rectifier. This will reduce the cost and size of the circuit. (ii) The PIV ratings are all low and do not indicate a preference for one circuit over another. (iii) The peak current values are lower for the full-wave and full-wave bridge rectifiers and also indicate an advantage for these circuits. (iv) We must choose between use of a center-tapped transformer (full-wave) or two extra diodes (bridge). At a current of 15 A, the diodes are not expensive and a four-diode bridge should be easily found. The final choice would be made based upon cost of available components. 3.113 200-V, 3-A power supply with Vr ≤ 4 V. Assume Von = 1 V. Rectifier Type Half Wave Full Wave Full Wave Bridge Peak Current 189 A 94.3 A 94.3 A PIV 402 V 402 V 202 V 12,500 μF 6250 μF 6250 μF Filter Capacitor (i) The the half-wave rectifier requires a larger value of C which may lead to more cost. (ii) The PIV ratings are all low enough that they do not indicate a preference for one circuit over another. (iii) The peak current values are lower for the full-wave and full-wave bridge rectifiers and also indicate an advantage for these circuits. (iv) We must choose between use of a center-tapped transformer (full-wave) or two extra diodes (bridge). At a current of 3 A, the diodes are not expensive and a four-diode bridge should be easily found. The final choice would be made based upon cost of available components. 71 3.114 3000-V, 1-A power supply with Vr ≤ 120 V. Assume Von = 1 V. Rectifier Type Half Wave Full Wave Full Wave Bridge Peak Current 133 A 66.6 A 66.6 A PIV 6000 V 6000 V 3000 V Filter Capacitor 41.7 μF 20.8 μF 20.8 μF (i) A series string of multiple capacitors will normally be required to achieve the voltage rating. (ii) The PIV ratings are high, and the bridge circuit offers an advantage here. (iii) The peak current values are lower for the full-wave and full-wave bridge rectifiers but neither is prohibitively large. (iv) We must choose between use of a center-tapped transformer (full wave) or extra diodes (bridge). With a PIV of 3000 or 6000 volts, multiple diodes may be required to achieve the require PIV rating. 3.115 5V 5 − VD 5 − 0.6 = 5 mA | I F = = = 4.4 mA 1kΩ 1kΩ 1kΩ ⎛ −3 − 0.6 4.4mA ⎞ Ir = = −3.6 mA | τ S = (7ns) ln⎜1− ⎟ = 5.59 ns 1kΩ ⎝ −3.6mA ⎠ ( ) iD 0 + = 3.116 *Problem 3.143 - Diode Switching Delay V1 1 0 PWL(0 0 0.01N 5 10N 5 10.02N -3 20N -3) R1 1 2 1K D1 2 0 DIODE .TRAN .01NS 20NS .MODEL DIODE D TT=7NS IS=1E-15 .PROBE V(1) V(2) I(V1) .OPTIONS RELTOL=1E-6 .OP .END 10 5 v1 vD 0 -5 Time -10 0s Simulation results give 72 S = 4.4 ns. 5ns 10ns 15ns 20ns 3.117 5V 5 − Von 5 − 0.6 = 1 A | IF = = = 0.880 A 5Ω 1Ω 5Ω ⎛ −3 − 0.6 0.880 A ⎞ = −0.720 A | τ S = (250ns) ln⎜1− IR = ⎟ = 200 ns 5Ω ⎝ −0.720 A ⎠ ( ) iD 0 + = 3.118 *Problem 3.145(a) - Diode Switching Delay V1 1 0 DC 1.5 PWL(0 0 .01N 1.5 7.5N 1.5 7.52N -1.5 15N -1.5) R1 1 2 0.75K D1 2 0 DIODE .TRAN .02NS 100NS .MODEL DIODE D TT=50NS IS=1E-15 CJO=0.5PF .PROBE V(1) V(2) I(V1) .OPTIONS RELTOL=1E-6 .OP .END For this case, simulation yields 2.0 v1 1.0 vD 0 -1.0 Time -2.0 0s 5ns 10ns 15ns 20ns 25ns S = 3 ns. *Problem 3.145(b) - Diode Switching Delay V1 1 0 DC 1.5 PWL(0 1.5 7.5N 1.5 7.52N -1.5 15N -1.5) R1 1 2 0.75K D1 2 0 DIODE .TRAN .02NS 100NS .MODEL DIODE D TT=50NS IS=1E-15 CJO=0.5PF .PROBE V(1) V(2) I(V1) .OPTIONS RELTOL=1E-6 .OP .END 2.0 v1 1.0 vD 0 -1.0 Time -2.0 0s 10ns 20ns 30ns For this case, simulation yields 40ns S = 15.5 ns. 73 In case (a), the charge in the diode does not have time to reach the steady-state value given by Q = (1mA)(50ns) = 50 pC. At most, only 1mA(7.5ns) = 7.5 pC can be stored in the diode. Thus is turns off more rapidly than predicted by the storage time formula. It should turn off in approximately t = 7.5pC/3mA = 2.5 ns which agrees with the simulation results. In (b), the diode charge has had time to reach its steady-state value. Eq. (3.103) gives: (50 ns) ln (1-1mA/(3mA)) = 14.4 ns which is close to the simulation result. 3.119 [ ] IC = 1−10−15 exp(40VC )−1 A | For VC = 0, I SC = 1A VOC = 1 ⎛ 1 ⎞ ln⎜1+ −15 ⎟ = 0.864 V 40 ⎝ 10 ⎠ [ [ ]] P = VC IC = VC 1−10−15 exp(40VC )−1 [ ] dP = 1−10−15 exp(40VC )−1 − 40x10−15 VC exp(40VC ) = 0 dVC Using the computer to find VC yields VC = 0.7768 V, IC = 0.9688 A, and Pmax = 7.53 Watts 3.120 (a) For VOC, each of the three diode teminal currents must be zero, and 1 VOC = VC1 + VC 2 + VC 3 = V ln(1.05x1015 )+ ln(1.00x1015 )+ ln(0.95x1015 ) = 2.59 V 40 (b) For ISC, the external currents cannot exceed the smallest of the short circuit current [ ] of the individual diodes. Thus, ISC = min[1.05A,1.00A,0.95A] = 0.95 A Note that diode three will be reversed biased in part (b). Using the computer to find VC yields VC = 0.7768 V, IC = 0.9688 A, and Pmax = 7.53 Watts 3.121 hc λ= E ) = 1.11 μm - far infrared 1.12eV (1.602x10 j / eV ) 6.625x10 J − s(3x10 m / s) = 0.875 μm - near infrared (b) λ = 1.42eV (1.602x10 j / eV ) (a) λ = ( 6.625x10−34 J − s 3x108 m / s −19 −34 8 −19 74 CHAPTER 4 4.1 (a) VG > VTN corresponds to the inversion region (b) VG << VTN corresponds to the accumulation region (c) VG < VTN corresponds to the depletion region 4.2 (a) ( ) −14 3.9εo 3.9 8.854x10 F / cm F nF C = = = = 6.91x10−8 2 = 69.1 2 −9 Tox Tox 50x10 m(100cm / m) cm cm εox " ox (b), (c) & (d): Scaling the result from part (a) yields Cox" = 69.1 nF 50nm nF nF 50nm nF nF 50nm nF = 173 2 | Cox" = 69.1 2 = 346 2 | Cox" = 69.1 2 = 691 2 2 cm 20nm cm cm 10nm cm cm 20nm cm 4.3 εs Cd = 2εs (0.75V ) qN B = ( 11.7 8.854x10−14 F / cm ( 2(11.7) 8.854x10−14 F / cm −19 1.602x10 (10 15 / cm 4.4 (a) 3 ) ) )(0.75V ) = 10.5x10−9 F / cm 2 ( ) −14 3.9εo ⎛ cm 2 ⎞ 3.9 8.854x10 F / cm K = μ nC = μ n = μn = ⎜ 500 ⎟ Tox Tox V − sec ⎠ 50x10−9 m(100cm / m) ⎝ ' n εox " ox F A μA = 34.5 x 10−6 2 = 34.5 2 V − sec V V (b) & (c) Scaling the result from part (a) yields Kn' = 34.5x10−6 Kn' = 34.5 μA 50nm 2 V 20nm = 86.3 μA V | Kn' = 34.5 2 4.5 (a) Q (b) Q " " = C (VGS − VTN )= εox = C (VGS − VTN )= εox " ox " ox Tox Tox (V GS (V GS − VTN ) = − VTN )= μA 50nm 2 V 10nm = 173 μA V 2 | Kn' = 34.5 ( 3.9 8.854x10−14 F / cm ( 3.9 8.854x10−14 F / cm 5nm −7 )(2V )= 6.91x10 10x10 m(100cm / m) −9 V 2 )(1V )= 1.38x10 25x10 m(100cm / m) −9 μA 50nm −7 = 345 μA V2 C cm 2 C cm 2 75 4.6 ⎛ V ⎞ cm2 ⎞⎛ 6 cm v = − μ E = − 500 a ⎜ ⎟⎜2000 ⎟ = −1.00x10 () n n cm ⎠ s V − s ⎠⎝ ⎝ ⎛ V ⎞ cm2 ⎞⎛ cm (a) vn = −μnE = −⎜400 V − s ⎟⎜⎝4000 cm ⎟⎠ = −1.60x106 s ⎠ ⎝ 4.7 The carrier velocity must increase as the carriers travel down the channel to compensate for the decrease in carrier density 4.8 (a) 0 < 0.8V → I D = 0 (b) VGS - VTN = 0.2V , VDS = 0.25V → Saturation region ⎛ 200 μA ⎞⎛ 5μm ⎞ 2 K' W ⎛ V ⎞ I D = n ⎜VGS − VTN − DS ⎟VDS = ⎜ ⎟(1− 0.8) = 40.0 μA 2 ⎟⎜ 2 L⎝ 2 ⎠ ⎝ 2 V ⎠⎝ 0.5μm ⎠ (c) VGS - VTN = 1.2V , VDS = 0.25V → triode region ⎛ 0.25 ⎞ W⎛ μA ⎞⎛ 5μm ⎞⎛ V ⎞ I D = Kn' ⎜VGS − VTN − DS ⎟VDS = ⎜200 2 ⎟⎜ ⎟⎜2 − 0.8 − ⎟(0.25) = 538 μA 2 ⎠ 2 ⎠ L⎝ V ⎠⎝ 0.5μm ⎠⎝ ⎝ (d ) VGS - VTN = 2.2V , VDS = 0.25V → triode region ⎛ 0.25 ⎞ W⎛ μA ⎞⎛ 5μm ⎞⎛ V ⎞ I D = Kn' ⎜VGS − VTN − DS ⎟VDS = ⎜200 2 ⎟⎜ ⎟⎜3 − 0.8 − ⎟(0.25)= 1.04 mA 2 ⎠ 2 ⎠ L⎝ V ⎠⎝ 0.5μm ⎠⎝ ⎝ mA W ⎛ μA ⎞⎛ 5μm ⎞ (e) Kn = Kn' L = ⎜⎝200 V 2 ⎟⎠⎜⎝ 0.5μm ⎟⎠ = 2.00 V 2 4.9 mA W μA ⎛ 60μm ⎞ = 200 2 ⎜ ⎟ = 4.00 2 L V V ⎝ 3μm ⎠ mA mA μA ⎛ 3μm ⎞ μA ⎛ 10μm ⎞ (b) Kn = 200 V 2 ⎜⎝ 0.15μm ⎟⎠ = 4.00 V 2 | (c) Kn = 200 V 2 ⎜⎝ 0.25μm ⎟⎠ = 8.00 V 2 (a) K n = Kn' 4.10 (a) 0 < 1V → cutoff region, I D = 0 (b) 1V = 1V → cutoff region, I D =0 (c) VGS - VTN = 1V , VDS = 0.1V → triode region ⎛ 0.1⎞ W⎛ μA ⎞⎛10μm ⎞⎛ V ⎞ I D = Kn' ⎜VGS − VTN − DS ⎟VDS = ⎜250 2 ⎟⎜ ⎟⎜2 −1− ⎟(0.1) = +231 μA 2 ⎠ 2 ⎠ L⎝ V ⎠⎝ 1μm ⎠⎝ ⎝ 76 (d) VGS - VTN = 2V , VDS = 0.1V → triode region ⎛ W⎛ μA ⎞⎛10μm ⎞⎛ V ⎞ 0.1⎞ I D = Kn' ⎜VGS − VTN − DS ⎟VDS = ⎜250 2 ⎟⎜ ⎟⎜3 −1− ⎟(0.1)= +488 μA 2 ⎠ L⎝ 2 ⎠ V ⎠⎝ 1μm ⎠⎝ ⎝ W ⎛ μA ⎞⎛10μm ⎞ mA (e) Kn = Kn' L = ⎜⎝250 V 2 ⎟⎠⎜⎝ 1μm ⎟⎠ = 2.50 V 2 4.11 Identify the source, drain, gate and bulk terminals and find the current I in the transistors in Fig. P-4.3. W = L +0.2 V 10 1 D G +5 (a) B V + V S - GS S B D 10 1 V G +5 W = L I + DS + VGS I -0.2 V - DS + (b) (a) VGS = VG − VS = 5V VDS = VD − VS = 0.2V → Triode region operation ⎛ W⎛ μA ⎞⎛10 ⎞⎛ V ⎞ 0.2 ⎞ I = I D = Kn' ⎜VGS − VTN − DS ⎟VDS = ⎜100 2 ⎟⎜ ⎟⎜ 5 − 0.70 − ⎟0.2 = +840 μA 2 ⎠ L⎝ 2 ⎠ V ⎠⎝ 1 ⎠⎝ ⎝ (b) VGS = VG − VS = 5 − (−0.2) = 5.2V VDS = VD − VS = 0 − (−0.2)= 0.2V ⎛ 0.2 ⎞ μA ⎞⎛ 10 ⎞⎛ I = −I S = −⎜100 2 ⎟⎜ ⎟⎜5.2 − 0.70 − ⎟0.2 = −880 μA 2 ⎠ V ⎠⎝ 1 ⎠⎝ ⎝ 4.12 ⎛ 0.5 ⎞ μA ⎞⎛ 10 ⎞⎛ (a) I = ⎜100 2 ⎟⎜ ⎟⎜5 − 0.75 − ⎟0.5 = 2.00 mA 2 ⎠ V ⎠⎝ 1 ⎠⎝ ⎝ ⎛ 0.2 ⎞ μA ⎞⎛10 ⎞⎛ (b) I = ⎜100 2 ⎟⎜ ⎟⎜3 − 0.75 − ⎟0.2 = 430 μA 2 ⎠ V ⎠⎝ 1 ⎠⎝ ⎝ 4.13 (a) VGS = VG − VS = 5 − (−0.5) = 5.5 V VDS = VD − VS = 0 − (−0.5)= 0.5 V ⎛ 0.5 ⎞ μA ⎞⎛10 ⎞⎛ I = −I S = −⎜100 2 ⎟⎜ ⎟⎜5.5 − 0.75 − ⎟0.5 = −2.25 mA 2 ⎠ V ⎠⎝ 1 ⎠⎝ ⎝ (b) V GS = VG − VS = 3 − (−1) = 4 V VDS = VD − VS = 0 − (−1) = 1 V ⎛ 1⎞ μA ⎞⎛10 ⎞⎛ I = −I S = −⎜100 2 ⎟⎜ ⎟⎜4 − 0.75 − ⎟1 = −2.75 mA 2⎠ V ⎠⎝ 1 ⎠⎝ ⎝ 77 4.14 Kn = Kn' (a) W = W L Kn 4mA /V 2 L = (0.5μm)= 20 μm Kn' 100μA /V 2 (b) W = 800μA /V 2 (0.5μm)= 4 μm 100μA /V 2 4.15 (a) R on 1 = (b) R on Kn' = W (VGS − VTN ) L = 1 = 23.0 Ω ⎞ ⎛ −6 100 100x10 ⎜ ⎟(5 − 0.65) ⎝ 1 ⎠ 1 = 35.7 Ω ⎞ ⎛ −6 100 100x10 ⎜ ⎟(3.3 − 0.50) ⎝ 1 ⎠ 4.16 Ron = 1 or W 1 = ' L Kn (VGS − VTN )Ron W (VGS − VTN ) L W 1 4.71 W 1 7.84 (a) = = | (b) = = −6 −6 L 100x10 (5 − 0.75)(500) 1 L 100x10 (3.3 − 0.75)(500) 1 Kn' 4.17 Ron ≤ 0.1V ID 5 A = 0.020Ω = 20mΩ | Kn = = = 17.0 2 5A V (VGS − VTN − 0.5VDS )VDS 5 − 2 − 0.5(0.1) (0.1) ( Note that this will require ) W Kn 17.0 170 = = = L Kn' 0.1 1 4.18 Picking two values in saturation : K K 2 2 395μA = n (4 − VTN ) and 140μA = n (3 − VTN ) 2 2 Taking the ratio of these two equations : μA 125 2 W V = 1.25 = L 100 μA 1 2 V From the graph, VTN is somewhat less than 2 V. VTN > 0 → enhancement - mode transistor 395 (4 − VTN ) μA = 2 → VTN = 1.5 V → K n = 125 140 (3 − VTN ) V2 2 78 4.19 Using the parameter values from problem 4.22: 800uA VGS = 5 V VGS = 4.5 V Drain Current (A) 600uA VGS = 4 V 400uA VGS = 3.5 V 200uA VGS = 3 V VGS = 2.5 V VGS = 2 V 0 A 0V 1.0V 2.0V 3.0V 4.0V 5.0V 6.0V Drain-Source Voltage (V) 4.20 (a) For VGS = 0, VGS ≤ VTN and ID = 0 (b) For VGS = 1 V, VGS = VTN and ID = 0 (c ) VGS − VTN ID = mA 375 μA ⎛ 5μm ⎞ μA ⎛ 5μm ⎞ 2 2 ' W = 375 2 ⎜ ⎟ = 3.75 2 ⎟(2 −1) V = 1.88 mA | K n = K n 2 ⎜ V 2 V ⎝ 0.5μum ⎠ L V ⎝ 0.5um ⎠ (d) VGS − VTN ID = = 2 -1 =1V and VDS = 3.3 | VDS > (VGS − VTN ) so the saturation region is correct = 3 -1 = 2V and VDS = 3.3 | VDS > (VGS − VTN ) so the saturation region is correct 375 μA ⎛ 5μm ⎞ 2 2 ⎟(3 −1) V = 7.50 mA 2 ⎜ 2 V ⎝ 0.5μm ⎠ 4.21 (a) For VGS = 0, VGS < VTN and ID = 0 (b) For VGS = 1 V, VGS < VTN and ID = 0 (c ) VGS − VTN ID = 200 μA ⎛10μm ⎞ μA ⎛ 10μm ⎞ mA 2 2 ' W V = 250 μ A | K = K = 200 2 −1.5 ⎜ ⎟ ⎟ = 2.00 2 ( ) n n 2 2 ⎜ 2 V ⎝ 1um ⎠ L V ⎝ 1um ⎠ V (d) VGS − VTN ID = = 2 -1.5 = 0.5V and VDS = 4 | VDS > (VGS − VTN ) so the saturation region is correct = 3 -1.5 =1.5V and VDS = 4 | VDS > (VGS − VTN ) so the saturation region is correct 200 μA ⎛10μm ⎞ 2 2 ⎟(3 −1.5) V = 2.25 mA 2 ⎜ 2 V ⎝ 1μm ⎠ 79 4.22 (a) VGS - VTN = 2 - 0.75 = 1.25 V and VDS = 0.2 V. VDS < VGS - VTN so the transistor is operating in the triode region. ⎛ V ⎞ 0.2 ⎞ W⎛ μA ⎞⎛10 ⎞⎛ ⎜VGS − VTN − DS ⎟VDS = ⎜200 2 ⎟⎜ ⎟⎜ 2 − 0.75 − ⎟0.2 = 460 μA ⎝ 2 ⎠ 2 ⎠ L⎝ V ⎠⎝ 1 ⎠⎝ (b) VGS - VTN = 2 - 0.75 = 1.25 V and VDS = 2.5 V. VDS > VGS - VTN so the transistor is operating in the saturation region. ⎛ 200 μA ⎞⎛10 ⎞ K' W 2 2 ID = n ⎟(2 − 0.75) = 1.56 mA (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L (c) VGS < VTN so the transistor is cutoff with ID = 0. ⎛ 300 ⎞ ID ∝ K n' so (a) ID = ⎜ (d) ⎟460μA = 690μA (b) ID = 2.34 mA (c) ID = 0 ⎝ 200 ⎠ ID = K n' 4.23 (a) VGS - VTN = 4 V, VDS = 6 V. VDS > VGS - VTN --> Saturation region (b) VGS < VTN --> Cutoff region (c) VGS - VTN = 1 V, VDS = 2 V. VDS > VGS - VTN --> Saturation region (d) VGS - VTN = 0.5 V, VDS = 0.5 V. VDS = VGS - VTN --> Boundary between triode and saturation regions (e) The source and drain of the transistor are now reversed because of the sign change in VDS. Assuming the voltages are defined relative to the original S and D terminals as in Fig. P4.11(b), VGS = 2 - (-0.5) = 2.5 V, VGS - VTN = 2.5 - 1 = 1.5 V, and VDS = 0.5 V --> triode region (f) The source and drain of the transistor are again reversed because of the sign change in VDS. Assuming the voltages are defined relative to the original S and D terminals as in Fig. P4.11(b), VGS = 3 - (-6) = 9 V, VGS - VTN = 9 - 1 = 8.0 V, and VDS = 6 V --> triode region D --> 'S' - D --> 'S' G G 6.0 V 0.5 V + + 2V (e) + S --> 'D' VG'S' = +2.5 V VD'S' = +0.5 V 80 3V (f) + S --> 'D' V G'S' = +9.0 V V D'S' = +6.0 V 4.24 (a) VGS - VTN = 2.6 V, VDS = 3.3 V. VDS > VGS - VTN --> Saturation region (b) VGS < VTN --> Cutoff region (c) VGS - VTN = 1.3 V, VDS = 2 V. VDS > VGS - VTN --> Saturation region (d) VGS - VTN = 0.8 V, VDS = 0.5 V. VDS < VGS - VTN --> triode region (e) The source and drain of the transistor are now reversed because of the sign change in VDS. Assuming the voltages are defined relative to the original S and D terminals as in Fig. 4.54(b), VGS = 2 - (-0.5) = 2.5 V, VGS - VTN = 2.5 – 0.7 = 1.8 V, and VDS = 0.5 V --> triode region (f) The source and drain of the transistor are again reversed because of the sign change in VDS. Assuming the voltages are defined relative to the original S and D terminals as in Fig. 4.54(b), VGS = 3 - (-3) = 6 V, VGS - VTN = 6 – 0.7 = 5.3 V, and VDS = 3 V --> triode region 4.25 R R 2 4 V D DD G B + - S R R 1 4.26 3 +V DD D G I B S +V DD D D G B G I B S S D D B B G G S (a) S (b) 4.27 81 VDS = 3.3V, VGS – VTN = 1.3 V; VDS > VGS - VTN so the transistor is saturated. (a) gm = K n (VGS − VTN ) = 250 μA ⎛ 20μm ⎞ ⎜ ⎟(2 − 0.7) = 6.50 mS V 2 ⎝ 1μm ⎠ (b) gm = K n (VGS − VTN ) = 250 μA ⎛ 20μm ⎞ ⎜ ⎟(3.3 − 0.7) = 13.0 mS V 2 ⎝ 1μm ⎠ 4.28 (a) gm = ΔiD 760 −140 μA = = 310 μS | As a check, we can use the results from Problem 4.22. ΔvGS 5−3 V gm = K n (VGS − VTN ) = 125 (b) gm = ΔiD ΔvGS μA (4 −1.5)V = 313 μS V2 μA 390 −15 μA = = 188 μS | Checking : gm = 125 2 (3 −1.5)V = 188 μS V 4−2 V 4.29 VDS > VGS - VTN so the transistor is saturated. Kn 250 μA 2 2 5 − 0.75) (1+ 0.025(6)) = 2.60 mA (VGS − VTN ) (1+ λVDS ) = 2 ( 2 2 V K 250 μA 2 2 (b) ID = n (VGS − VTN ) = 5 − 0.75) = 2.26 mA 2 ( 2 2 V (a) ID = 4.30 VDS > VGS - VTN so the transistor is saturated. Kn 500 μA 2 2 4 −1) (1+ 0.02(5)) = 2.48 mA (VGS − VTN ) (1+ λVDS ) = 2 ( 2 2 V K 500 μA 2 2 (b) ID = n (VGS − VTN ) = 4 −1) = 2.25 mA 2 ( 2 2 V (a) ID = 4.31 (a) The transistor is saturated by connection. ID = 12V − VGS 100x10−6 ⎛10 ⎞ A 2 = ⎜ ⎟ 2 (VGS − 0.75V ) 5 ⎝ 1 ⎠V 10 Ω 2 12.5VGS2 −17.8VGS − 4.97 = 0 VGS = 0.266V , 1.214V ⇒ VGS = 1.214 V since it must exceed 0.75V ID = 12 −1.214 = 108 μA 10 5 (b) ID = 82 Checking : 100x10−6 ⎛10 ⎞ A 2 ⎜ ⎟ 2 (1.214 − 0.75V ) = 108 μA ⎝ 1 ⎠V 2 12V − VGS 1000x10−6 A 2 = V − 0.75V ) (1+ 0.025VGS ) 5 2 ( GS 10 Ω 2 V Starting with the solution from part (a) and solving iteratively yields VGS = 1.20772 V and ID = 108 μA, essentially no change. (c) 12V − VGS 100x10−6 ⎛ 25 ⎞ A 2 ID = = ⎜ ⎟ 2 (VGS − 0.75V ) 5 ⎝ 1 ⎠V 10 Ω 2 62.5VGS2 − 91.75VGS + 11.16 = 0 VGS = 0.446V , 1.046V ⇒ VGS = 1.046 V since VGS must exceed the threshold voltage. 12 −1.046 ID = = 110 μA 10 5 100x10−6 ⎛ 25 ⎞ A 2 Checking : ID = ⎜ ⎟ 2 (1.046 − 0.75V ) = 110 μA ⎝ 1 ⎠V 2 4.32 (a) The transistor is saturated by connection. 12V − VGS 100x10−6 ⎛10 ⎞ A 2 ID = = ⎜ ⎟ 2 (VGS − 0.75V ) 4 ⎝ 1 ⎠V 5x10 Ω 2 31.25VGS2 − 45.88VGS + 5.58 = 0 VGS = 0.0588V , 1.401V ⇒ VGS = 1.401 V since VGS must exceed the threshold voltage. 12 −1.401 100x10−6 ⎛10 ⎞ A 2 = 212 μ A Checking : I = ⎜ ⎟ 2 (1.401− 0.75V ) = 212 μA D 4 ⎝ 1 ⎠V 5x10 2 −6 12V − VGS 1000x10 A 2 = V − 0.75V ) (1+ 0.02VGS ) (b) ID = 4 2 ( GS 5x10 Ω 2 V ID = Starting with the solution from part (a) and solving iteratively yields VGS = 1.3925 V and IDS = 212 μA, essentially no change 4.33 (a) Since VDS = VGS and VTN > 0 for both transistors, both devices are saturated. K n' W K n' W 2 2 I = V − V and I = ( GS1 TN ) (VGS 2 − VTN ) . Therefore D1 D2 2 L 2 L From the circuit, however, ID2 must equal ID1 since IG = 0 for the MOSFET: K n' W K n' W 2 2 I = ID1 = ID 2 or (VGS1 − VTN ) = (VGS 2 − VTN ) 2 L 2 L which requires VGS1 = VGS2. Using KVL: VDD = VDS1 + VDS 2 = VGS1 + VGS 2 = 2VGS 2 V VGS1 = VGS 2 = DD = 5V 2 ' K W 100 μA 10 2 2 I= n (VGS1 − VTN ) = (5 − 0.75) V 2 = 9.03 mA 2 2 V 1 2 L (b) The current simply scales by a factor of two (see last equation above), and ID = 18.1 mA. (c) For this case, 83 K n' W K n' W 2 2 V − V 1 + λ V and I = ( GS1 TN ) ( (VGS 2 − VTN ) (1 + λVDS2 ). DS1 ) D2 2 L 2 L Since VGS = VDS for both transistors K n' W K n' W 2 2 ID1 = (VGS1 − VTN ) (1 + λVGS1 ) and ID 2 = (VGS 2 − VTN ) (1 + λVGS2 ) 2 L 2 L and ID1 = ID2 = I K' W K n' W 2 2 (VGS1 − VTN ) (1 + λVGS1 ) = n (VGS 2 − VTN ) (1 + λVGS2 ) 2 L 2 L which again requires VGS1 = VGS2 = VDD/2 = 5V. K' W 100 μA 10 2 2 I= n (VGS1 − VTN ) (1+ λVDS ) = (5 − 0.75) V 2 (1+ (.04 )5) = 10.8 mA 2 2 L 2 V 1 ID1 = 4.34 (a) Since VDS = VGS and VTN > 0 for both transistors, both devices are saturated (“by connection”). K n' ⎛ W ⎞ K n' ⎛ W ⎞ 2 2 ID1 = ⎜ ⎟ (VGS1 − VTN ) and ID 2 = ⎜ ⎟ (VGS 2 − VTN ) . Therefore 2 ⎝ L ⎠1 2 ⎝ L ⎠2 From the circuit, however, ID2 must equal ID1 since IG = 0 for the MOSFET: K n' ⎛ 10 ⎞ K n' ⎛ 40 ⎞ 2 2 V I = ID1 = ID 2 or − V = ⎜ ⎟( GS1 TN ) ⎜ ⎟(VGS 2 − VTN ) 2 ⎝1⎠ 2 ⎝1⎠ which requires VGS1 = 2VGS2 - VTN. Using KVL: VDD = VDS1 + VDS 2 = VGS 2 + VGS1 = 3VGS 2 − VTN V + VTN 10 + 0.75 VGS 2 = DD = = 3.583V VGS1 = 6.417 3 3 100 μA 10 K' W 2 2 I= n (VGS1 − VTN ) = (6.417 − 0.75) V 2 = 16.1 mA 2 2 V 1 2 L 100 μA 40 2 Checking : I = (3.583 − 0.75) V 2 = 16.1 mA which agrees. 2 2 V 1 (b) For this case with VGS = VDS for both transistors and ID1 = ID2, K' ⎛W ⎞ K' ⎛W ⎞ 2 2 ID1 = n ⎜ ⎟ (VGS1 − VTN ) (1 + λVGS1 ) and ID 2 = n ⎜ ⎟ (VGS 2 − VTN ) (1 + λVGS2 ) 2 ⎝ L ⎠1 2 ⎝ L ⎠2 where VGS2 = VDD – VGS1. Therefore, K ' ⎛ 40 ⎞ K n' ⎛10 ⎞ 2 2 ⎜ ⎟(VGS1 − VTN ) (1 + λVGS1 ) = n ⎜ ⎟(10 − VGS1 − VTN ) (1 + λ(10 − VGS1 )) 2 ⎝1⎠ 2 ⎝1⎠ VGS1 = 6.3163, VGS2 = 3.6837, ID1 = 20.4 mA, Checking: ID2 = 20.4 mA which agrees. 84 4.35 (a) Since VDS = VGS and VTN > 0 for both transistors, both devices are saturated (“by connection”). K n' ⎛ W ⎞ K n' ⎛ W ⎞ 2 2 V − V and I = ⎜ ⎟ ⎜ ⎟ (VGS 2 − VTN ) . ( ) GS1 TN D2 Therefore 2 ⎝ L ⎠1 2 ⎝ L ⎠2 From the circuit, however, ID2 must equal ID1 since IG = 0 for the MOSFET: K n' ⎛ 25 ⎞ K n' ⎛12.5 ⎞ 2 2 I = ID1 = ID 2 or ⎜ ⎟(VGS1 − VTN ) = ⎜ ⎟(VGS 2 − VTN ) 2 ⎝1⎠ 2 ⎝ 1 ⎠ Solving for VGS2 yields: VGS 2 = 2VGS1 − 2 −1 VTN ID1 = ( ) Also, VDD = VDS1 + VDS 2 or VGS1 = 10 − VGS 2 VGS1 = 10 + ( 2 −1)V TN 1+ 2 = 4.271V VGS 2 = 5.729V 100 μA ⎛ 25 ⎞ K n' W 2 2 2 ⎟(4.271− 0.75) V = 15.5 mA (VGS1 − VTN ) = 2 ⎜ 2 V ⎝1⎠ 2 L 100 μA ⎛ 12.5 ⎞ 2 2 Checking : I = ⎟(5.729 − 0.75) V = 15.5 mA - agrees. 2 ⎜ 2 V ⎝ 1 ⎠ (b) For this case with VGS = VDS for both transistors and ID1 = ID2, K' ⎛W ⎞ K' ⎛W ⎞ 2 2 ID1 = n ⎜ ⎟ (VGS1 − VTN ) (1 + λVGS1 ) and ID 2 = n ⎜ ⎟ (VGS 2 − VTN ) (1 + λVGS2 ) 2 ⎝ L ⎠1 2 ⎝ L ⎠2 I= where VGS2 = VDD – VGS1. Therefore, K n' ⎛ 40 ⎞ K n' ⎛10 ⎞ 2 2 ⎜ ⎟(VGS1 − VTN ) (1 + λVGS1 ) = ⎜ ⎟(10 − VGS1 − VTN ) (1 + λ(10 − VGS1 )) 2 ⎝1⎠ 2 ⎝1⎠ VGS1 = 4.3265 V, VGS2 = 5.6735 V, ID1 = 19.4 mA, Checking: ID2 = 19.4 mA – both agree 4.36 VGS - VTN = 5 - (-2) = 7 V > VDS = 6 V so the transistor is operating in the triode region. 6⎞ −6 ⎛ (a) ID = 250x10 ⎜5 − (−2) − ⎟6 = 6.00 mA ⎝ 2⎠ (b) Our triode region model is independent of λ, so ID = 6.00 mA. 4.37 Since VDS = VGS, and VTN < 0 for an NMOS depletion mode device, VGS - VTN will be greater than VDS and the transistor will be operating in the triode region. 85 4.38 (a) VDS = 6V | VGS − VTN = 0 − (−3) = 3V so the transistor is saturated 2 Kn 250 μA 2 0 − (−3V )] = 1.13 mA (VGS1 − VTN ) = 2 [ 2 V 2 2 250 μA 0 − (−3V )] (1+ 0.025(6)) = 1.29 mA (b) ID = 2 [ 2 V ID = 4.39 D G +10 V -10 V 100 k Ω 100 k Ω I DS S G W = 10 L 1 S (a) I DS W = 10 L 1 D (b) (a) If the transistor were saturated, then 100x10−6 ⎛ 10 ⎞ 2 ID = ⎜ ⎟(−2) = 2.00 mA ⎝1⎠ 2 but this would require a power supply of greater than 200 V (2 mA x 100 kΩ). Thus the transistor must be operating in the triode region. 10V − VDS VDS ⎞ −3 ⎛ = 10 0 − −2 − ⎜ ⎟VDS ( ) ⎝ 10 5 Ω 2 ⎠ 10 − VDS = 50VDS (4 − VDS ) and VDS = 0.0504V using the quadratic equation. ⎛ 0.0504 ⎞ 10V − VDS ID = 10−3 ⎜2 − = 99.5 μA ⎟0.0504 = 99.5 μA Checking : ⎝ 2 ⎠ 10 5 Ω (b) For R = 50 kΩ and W/L = 20/1, ⎛ 10V − VDS V ⎞ = 2x10−3⎜ 0 − (−2) − DS ⎟VDS 4 ⎝ 5x10 Ω 2 ⎠ 10 − VDS = 50VDS (4 − VDS ), the same as part (a). ⎛ 0.0504 ⎞ 10V − VDS ID = 2x10−3 ⎜2 − = 199 μA ⎟0.0504 = 199 μA Checking : ⎝ 5x10 4 Ω 2 ⎠ (c) In this circuit, the drain and source terminals of the transistor are reversed because of the power supply voltage, and the current direction is also reversed. However, now VDS = VGS and since the transistor is a depletion-mode device, it is still operating in the triode region. 86 ⎛ 10V − VDS V ⎞ = 1000x10−6 ⎜VDS − (−2) − DS ⎟VDS 5 ⎝ 10 Ω 2 ⎠ 10 − VDS = 50VDS (4 + VDS ) and VDS = 0.04915V using the quadratic equation. ⎛ 0.04915 ⎞ 10V − VDS ID = 10−3 ⎜0.04915 − (−2) − = 99.5 μA ⎟0.04915 = 99.5 μA Checking : ⎝ 10 5 Ω 2 ⎠ (d) In this circuit, the drain and source terminals of the transistor are reversed because of the power supply voltage, and the current direction is also reversed. However, now VDS = VGS and since the transistor is a depletion-mode device, it is still operating in the triode region. ⎛ 10V − VDS V ⎞ = 2000x10−6⎜VDS − (−2) − DS ⎟VDS 4 ⎝ 5x10 Ω 2 ⎠ 10 − VDS = 50VDS (4 + VDS ) Same as part (c). VDS = 0.04915V using the quadratic equation. ⎛ 0.04915 ⎞ 10V − VDS ID = 10−3 ⎜0.04915 − (−2) − = 99.5 μA ⎟0.04915 = 99.5 μA Checking : ⎝ 10 5 Ω 2 ⎠ 4.40 See figures in previous problem but use W/L = 20/1. 25x10−6 ⎛ 20 ⎞ 2 = I ⎜ ⎟(−1) = 250 μA but this would require (a) If the transistor were saturated, then D 2 ⎝1⎠ a power supply of greater than 25 V. Thus the transistor must be operating in the triode region. ⎛ 20 ⎞⎛ 10V − VDS V ⎞ = 100x10−6 ⎜ ⎟⎜0 − (−1) − DS ⎟VDS 5 ⎝ 1 ⎠⎝ 10 Ω 2 ⎠ 10 − VDS = 100VDS (2 − VDS ) and VDS = 0.05105V using the quadratic equation. ⎛ 0.05105 ⎞ 10 − 0.0510 ID = 2.00x10−3 ⎜1− V = 99.5 μA ⎟0.05105 = 99.5 μA Checking : ⎝ 2 ⎠ 10 5 Ω (b) In this circuit, the drain and source terminals of the transistor are reversed because of the power supply voltage, and the current direction is also reversed. However, now VDS = VGS and since the transistor is a depletion-mode device, it is still operating in the triode region. ⎛ 20 ⎞⎛ V ⎞ VDS = 10 − (10 5 )(100x10−6 )⎜ ⎟⎜VDS − (−1) − DS ⎟VDS ⎝ 1 ⎠⎝ 2 ⎠ ⎛ V ⎞ VDS = 10 − 200VDS ⎜1+ DS ⎟ and VDS = 0.04858V using the quadratic equation. ⎝ 2 ⎠ ⎛ 0.04858 ⎞ 10 - 0.04858 V = 99.5 μA ID = 2000x10−6 ⎜1+ ⎟0.04858 = 99.5 μA Checking : ⎝ Ω 2 ⎠ 10 5 87 4.41 (a) VTN = 0.75 + 0.75 1.5 + 0.6 − 0.6 = 1.26V ( ) VGS − VTN = 2 −1.26 = 0.74V > VDS = 0.2V ⇒ Triode region ⎛10 ⎞⎛ 0.2 ⎞ ID = 200x10−6 ⎜ ⎟⎜ 2 −1.26 − ⎟0.2 = 256 μA (compared to 460 μA) ⎝ 1 ⎠⎝ 2 ⎠ (b) VGS − VTN = 2 −1.26 = 0.74V < VDS = 2.5V ⇒ Saturation region 200x10−6 ⎛ 10 ⎞ 2 ID = ⎜ ⎟(2 −1.26) = 548 μA (compared to 1.56 mA) ⎝1⎠ 2 (c) VGS < VTN so the transistor is cut off, and ID = 0. ⎛ 300 ⎞ (d) ID ∝ K n' so (a) ID = ⎜ ⎟256μA = 384 μA (b) ID = 822 μA (c) ID = 0 ⎝ 200 ⎠ 4.42 (a) VTN = 1.5 + 0.5 ( 4 + 0.75 − ) 0.75 = 2.16V | VGS < VTN ⇒ Cutoff & ID = 0 (b) ID = 0. The result is independent of VDS . 4.43 (a) VTN = 1+ 0.7 ( 3 + 0.6 − ) 0.6 = 1.79V VGS − VTN = 2.5 −1.79 = 0.71V < VDS = 5V ⇒ Saturation region 100x10−6 ⎛ 8 ⎞ 2 ⎜ ⎟(0.71) = 202 μA ⎝ 1⎠ 2 (b) 0.5 < 0.71 ⇒ Triode region ⎛ 8 ⎞⎛ 0.5 ⎞ ID = 100x10−6 ⎜ ⎟⎜ 0.71− ⎟0.5 = 184 μA ⎝ 1 ⎠⎝ 2 ⎠ ID = 4.44 0.85 = −1.5 + 1.5 VSB + 0.75 − 0.75 ( ) | Solving for VSB yields VSB = 5.17 V ( 5.17 + 0.75 − Checking : VTN = −1.5 + 1.5 ) 0.75 = 0.85 V 4.45 Using trial and error with a spreadsheet yielded: VTO = 0.74V γ = 0.84 V 2φ F = 0.87V RMS Error = 51.9 mV 88 4.46 −14 3.9εo ⎛ cm 2 ⎞ 3.9(8.854 x10 F /cm) (a) K = μ p C = μ p = μp = ⎜200 ⎟ Tox Tox V − sec ⎠ 50x10−9 m(100cm /m) ⎝ F μA K 'p = 13.8x10−6 = 13.8 2 V − sec V μA 50nm μA (b) Scaling the result from Part (a) yields: K n' = 13.8 2 = 34.5 2 V 20nm V μA 50nm μA = 69.0 2 (c) K n' = 13.8 2 V 10nm V μA 50nm μA = 138 2 (d) K n' = 13.8 2 V 5nm V ' p εox " ox 4.47 The pinchoff points and threshold voltage can be estimated directly from the graph: e. g. VGS = -3 V curve gives VTP = 2.5 - 3 = - 0.5 V or from the VGS = -5 V curve gives VTP = 4.5 - 5 = 0.5 V. Alternately, choosing two points in saturation, say ID = 1.25 mA for VGS = -3 V and ID = 4.05 mA for VGS = -5 V: ID1 (VGS1 − VTP ) = or ID 2 (VGS 2 − VTP ) 1.25 (−3 − VTP ) = 4.05 (−5 − VTP ) Solving for VTP yields : 0.8VTP = −0.4V and VTP = −0.500V . Solving for K p : K p = 2ID (VGS − VTP ) 2 = 2(1.25mA) (−3 + 0.5) 2 = 0.400 400 μA mA W V 2 = 10 | = = μA V2 L K 'p 1 40 2 V Kp 4.48 Using the values from the previous problem PMOS Output Characteristics 0.0045 0.004 0.0035 -2 V -3 V -3.5 V -4 V -4.5 V -5 V 0.003 0.0025 0.002 0.0015 0.001 0.0005 0 -6 -5 -4 -3 -2 -1 0 VDS (IDSAT, VDSAT): (0.45 mA,-1.5 V) (1.25 mA,-2.5 V) (1.8 mA,-3 V) (2.45 mA,-3.5 V) (3.7 mA,-4V) (4.05 mA,-4 V) 89 4.49 (a) VGS − VTP = −1.1+ 0.75 = −0.35V | VDS = −0.2V → Triode region (−0.2)⎤⎥ −0.2 = 40.0 μA 40μA ⎛ 20 ⎞⎡ ⎢ ID = −1.1− −0.75 − ⎜ ⎟ ( ) ( ) 2 ⎥⎦ V 2 ⎝ 1 ⎠⎢⎣ (b) VGS − VTP = −1.3 + 0.75 = −0.55V | VDS = −0.2V → Triode region (−0.2)⎤⎥ −0.2 = 72.0 μA 40μA ⎛ 20 ⎞⎡ ⎢ ID = −1.3 − −0.75 − ⎜ ⎟ ( ) 2 ⎥( ) V 2 ⎝ 1 ⎠⎢⎣ ⎦ [ )] ( (c) VTP = − 0.75 + .5 1+ .6 − −6 = −0.995V VGS − VTP = −1.1− (−0.995) = −0.105V | VDS = −0.2V → saturation region 1 ⎛ 40μA ⎞⎛ 20 ⎞ 2 ID = ⎜ 2 ⎟⎜ ⎟(−1.1+ 0.995) = 4.41 μA 2 ⎝ V ⎠⎝ 1 ⎠ (d) VGS − VTP = −1.3 + 0.995 = −0.305V | VDS = −0.2V → triode region 10μA ⎛ 10 ⎞⎡ (−0.2)⎤ −0.2 = 32.8 μA ID = ⎟⎢−1.3 − (−0.995) − ) ⎥( 2 ⎜ 2 ⎦ V ⎝ 1 ⎠⎣ 4.50 For PMOS : Ron = 1 or W 1 = ' L K p VGS − VTN Ron or W 1 = ' L K p VGS − VTN Ron W VGS − VTP L W 1 5810 W 1 2330 (a) = = | (b) = = −6 −6 L 40x10 −5 + 0.70 (1) 1 L 100x10 (5 − 0.70)(1) 1 K 'p 4.51 For PMOS : Ron = 1 W VGS − VTP L W 1 2.91 W 1 1.16 (a) = = | (b) = = −6 −6 L 40x10 −5 + 0.70 (2000) 1 L 100x10 (5 − 0.70)(2000) 1 90 K 'p 4.52 For PMOS : Ron = 1 K 'p W VGS − VTP L 1 = 29.4 Ω −6 ⎛ 200 ⎞ 40x10 ⎜ ⎟ −5 − (−0.75) ⎝ 1 ⎠ W 1 499 (c) = = −6 L 40x10 −5 − (−0.75)(11.8) 1 (a) Ron = 1 = 11.8 Ω ⎛ −6 200 ⎞ 100x10 ⎜ ⎟(5 − 0.75) ⎝ 1 ⎠ ⎛W ⎞ K' ⎛W ⎞ 500 Checking : ⎜ ⎟ = n' ⎜ ⎟ = 2.5(200) = ⎝ L ⎠ p K p ⎝ L ⎠n 1 (b) Ron = 4.53 +18 V R R4 2 R S VDD B G + - S B D R 1 G R D 3 (b) (a) 4.54 (a) For VIN = 0, the NMOS device is on with VGS = 5 and VSB = 0, and the PMOS transistor is off with VGS = 0, VO = 0, and VSB = 0. 1 Ron = = 235 Ω −6 (100x10 )(10)(5 − 0.75) (b) For VIN = 5V, the NMOS device is off with VGS = 0, and the PMOS transistor is on with VGS = -5V, VO = 5V, and VSB = 0. 1 Ron = = 235 Ω −6 (40x10 )(25)(−5 + 0.75) 4.55 Ron ≤ 0.1V 0.5A ID A = 0.2Ω K p = = = 0.629 2 0.5A V (VGS − VTP − 0.5VDS )VDS [−10V − (−2V ) − 0.5(−0.1V )](−0.1V ) 4.56 VTP = −0.75 − 0.5 ( 4 + 0.6 − ) 0.6 = −1.44V VGS - VTP = −1.5 − (−1.44 ) = −0.065 | VDS = −4V ⇒ Saturation region ID = 2 40x10−6 A ⎛ 25 ⎞ ⎟[−1.5 − (−1.44 )] = 1.80 μA 2⎜ V ⎝1⎠ 2 91 4.57 VGS − VTP = −1.5 − (−0.75) = −0.75V | VDS = −0.5V VGS - VTN < VDS ⇒ Triode region | ID = 40x10−6 A ⎛ 40 ⎞⎡ (−0.5)⎤ −0.5 = 400 μA ⎟⎢−1.5 − (−0.75) − ) ⎥( 2⎜ V ⎝ 1 ⎠⎣ 2 ⎦ 4.58 The PMOS transistor could be either an enhancement-mode or a depletion-mode device depending upon the specific values of R1, R2 and R4. Thus an enhancement device with VTP < 0 is correct and the symbol is correct. 4.59 If this PMOS transistor is conducting, then its threshold voltage must be greater than zero and it is a depletion-mode device. The symbol is that of an enhancement-mode device and is incorrect. 4.60 +18 V R4 R2 R S G VDD + D R1 G R D 3 (a) (b) 4.61 RD R2 75 k Ω 1.5 M Ω D VDD + G S R1 -3 V R S 1 MΩ 92 39 k Ω S 10 V 4.62 R D 75 k Ω R EQ 600 k Ω V EQ VDD D G S + -5 V 10 V RS 4V 39 k Ω 93 4.63 n+ 22 λ Metal Polysilicon 12 λ [(2x20)/(12x22)]= 0.152 or 15.2% 4.64 n+ 14 λ Metal Polysilicon 18 λ 94 [2x10/(18x14)]= 0.079 or 7.9% 4.65 Metal 12 λ n+ Polysilicon 12 λ (2x10/122)= 0.139 or 13.9% 4.66 Metal 12 λ n+ Polysilicon 14 λ [2x10/(14x12)] = 0.119 or 11.9% 95 4.67 (a) " Cox = εox Tox = ⎛ ⎝ (3.9)⎜8.854 x10−14 −6 5x10 cm F⎞ ⎟ cm ⎠ = 6.906x10−8 F cm 2 ⎛ F ⎞ " CGC = Cox WL = ⎜6.906x10−8 2 ⎟(20x10−4 cm)(2x10−4 cm)= 27.6 fF ⎝ cm ⎠ F " (b) Cox = 1.73 x 10−7 2 | CGC = 69.1 fF cm F " = 3.45 x 10−7 2 | CGC = 138 fF (c) Cox cm F " = 7.90 x 10−7 2 | CGC = 276 fF (d) Cox cm 4.68 " Cox = εox Tox = ⎛ ⎝ (3.9)⎜8.854 x10−14 F⎞ ⎟ cm ⎠ −6 1x10 cm = 3.46x10−7 F cm 2 ⎛ F ⎞ " CGC = Cox WL = ⎜ 3.46x10−7 2 ⎟(5x10−4 cm)(5x10−5 cm)= 8.64 fF ⎝ cm ⎠ 4.69 ' COL ⎛ ⎝ F⎞ ⎟ pF ε cm ⎠ = ox L = 0.5x10−4 cm)= 17.3 ( ⎛ cm ⎞ cm Tox 10x10−9 m⎜10 2 ⎟ ⎝ m⎠ (3.9)⎜8.854 x10−14 4.70 ⎛ ⎞ −15 F 10μm)(1μm) ⎜1.4 x10 2 ⎟( ⎛ μm ⎠ C WL F ⎞ ⎝ ' + COLW = + ⎜ 4 x10−15 (a) CGS = CGD = ⎟(10μm) = 47 fF 2 2 μm ⎠ ⎝ 2 " 2 ' WL + COL W = 14 fF + 40 fF = 49 fF (b) CGS = COX 3 3 ⎛ F ⎞ ' CGD = COL W = ⎜ 4 x10−15 ⎟(10μm) = 40 fF μm ⎠ ⎝ ⎛ F ⎞ ' W = ⎜ 4 x10−15 (c ) CGS = CGD = COL ⎟(10μm ) = 40 fF μm ⎠ ⎝ " OX 96 4.71 ⎛ ⎝ F⎞ ⎟ εox F cm ⎠ " Cox = = = 3.453x10−8 2 ⎛ ⎞ cm Tox cm 100x10−9 m⎜10 2 ⎟ ⎝ m⎠ (3.9)⎜8.854 x10−14 CGC ⎛ −4 cm ⎞ 2 ⎛ −8 F ⎞ 6 2 = C WL = ⎜ 3.453x10 ⎟(50x10 μm )⎜10 ⎟ = 17.3 nF ⎝ μm ⎠ cm 2 ⎠ ⎝ " ox 4.72 " L = 2Λ = 1μm | W =10L = 5μm | Cox = εox Tox = 3.9(8.854 x10−14 F /cm) −7 150x10 cm = 0.23 fF / μm 2 Triode region : " 0.23 fF / μm 2 )(5μm 2 ) ( Cox WL + CGSOW = + (0.02 fF / μm)(5μm) = 0.675 fF CGS = CGD = 2 2 2 " WL + CGSOW = 0.867 fF | CGS = CGSOW = 0.10 fF Saturation region : CGS = Cox 3 Cutoff : CGS = CGD = CGSOW = 0.10 fF 4.73 ⎛ F⎞ ⎟ cm ⎠ εox F " = 3.453x10−8 2 (a) Cox = T = ⎛ cm ⎞ cm ox 100x10−9 m⎜102 ⎟ m⎠ ⎝ ⎛ F ⎞ CGC = Cox" WL = ⎜3.453x10−8 2 ⎟ 10x10−4 cm 1x10−4 cm = 3.45 fF cm ⎠ ⎝ ⎛ F ⎞ (b) CGC = Cox" WL = ⎜⎝3.453x10−8 cm2 ⎟⎠ 100x10−4 cm 1x10−4 cm = 34.5 fF (3.9)⎜⎝8.854x10 −14 ( )( ( ) )( ) 97 4.74 CSB = C j AS + C jsw PS | CDB = C j AD + C jsw PD | AS = 50Λ2 = 12.5μm 2 | PS = 30Λ = 15μm Cj = εs w do ⎛ NA ND ⎞ ⎛10 201016 ⎞ 2εs ⎛ 1 1 ⎞ = 0.025ln + φ | φ = V ln ⎜ ⎟ j ⎜ 2 ⎟ ⎜ ⎟ = 0.921V j T 20 q ⎝ NA NA ⎠ ⎝ 10 ⎠ ⎝ ni ⎠ | w do = 2(11.7)(8.854 x10−14 )⎛ 1 1 ⎞ -5 w do = ⎜ 20 + 16 ⎟0.921 = 3.45x10 cm −19 ⎝ 10 10 ⎠ 1.602x10 Cj = CSB (11.7)(8.854 x10−14 F /cm) −5 = 3.00x10−8 F /cm 2 3.45x10 cm = (3.00x10−8 F /cm 2 )(12.5x10−8 cm 2 )+ 5x10−4 cm(3.00x10−8 F /cm 2 )(15x10−4 cm)= 26.3 fF CDB = CSB = 26.3 fF 4.75 KP = K 'n = K n L μA ⎛ 0.25μm ⎞ = 175 2 ⎜ ⎟ = 8.75U | VTO = VTN = 0.7 W V ⎝ 5μm ⎠ PHI = 2φ F = 0.8V | L = 0.25U | W = 5U | LAMBDA = 0.02 4.76 (a) VTO = 0.7 | PHI = 2φ F = 0.6 | GAMMA = 0.75 (b) VTO = 0.74 | PHI = 0.87 | GAMMA = 0.84 4.77 KP = K 'n = 50U VTO = VTN = 1 V L = 0.5U W = 2.5U LAMBDA = 0 4.78 KP = K 'n = 10U VTO = VTN = 1 V L = 0.6U W = 1.5U LAMBDA = 0 4.79 KP = K 'p = 10U VTO = VTP = −1 V L = 0.5U Using the - 3 - V curve, K P = 2 50μA [-3 - (-1)] 2 = 25 μA V2 W = 1.25U LAMBDA = 0 4.80 KP = K 'n = 25U VTO = VTN = 1 V L = 0.6U W = 0.6U LAMBDA = 0 98 NMOS i-v Characteristics for Load-Line Problems 800 5V Drain Current (uA) 600 400 4V 200 3V 2V 0 0 1 2 3 4 5 6 Drain Voltage (V) 99 4.81 For VDS = 0, ID = 4V = 0.588mA. For ID = 0,VDS = 4V . 6.8kΩ Also, VGS = 4V. From the graph, the transistor is operating below pinchoff in the triode region and the Q-point is Q-point: (350 μA, 1.7V) 800 5V Drain Current (uA) 600 Q-point (4.82) 400 4V Q-point (4.81) 200 3V 2V 0 0 1 2 3 4 5 6 Drain Voltage (V) 4.82 For VDS = 0, ID = 5V = 0.602mA. For ID = 0,VDS = 5V . 8.3kΩ For VGS = 5V, the Q-point is (450 μA, 1.25 V). From the graph in Prob. 4.81, the transistor is operating below pinchoff in the triode region. 4.83 800 5V Drain Current (uA) 600 Q-point (4.84) 400 4V Q-point (4.83) 200 3V 2V 0 0 1 2 3 Drain Voltage (V) 100 4 5 6 VDD = 3V | 6 =10 4 ID +V DS | VDS = 0, ID = 0.6mA | ID = 0, VDS = 6V 2 From the graph, Q-pt: (140 μA, 4.6V) in the saturation region. VGS = 4.84 VDD = 4V | 8 =10 4 ID +V DS | VDS = 6, ID = 0.2mA | VDS = 0, ID = 0.8mA 2 See graph for Problem 4.83: Q-pt: (390 μA, 4.1 V) in saturation region. VGS = 4.85 100kΩ 12V = 3.75V | Assume saturation 100kΩ + 220kΩ −6 ⎞ ⎛ ⎛ 5⎞ 2 3 3 100x10 3.75 = VGS + 24 x10 ID = VGS + 24 x10 ⎜ ⎟⎜ ⎟(VGS −1) 2 ⎝ ⎠⎝ 1 ⎠ (a) VGG = 6VGS2 −11VGS + 2.25 = 0 → VGS = 1.599V and ID = 89.7μA VDS = 12 − 36x10 3 ID = 8.77V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 24 x10 3 ID + VGS = 3.75V which is correct. Q − point : (89.7 μA, 8.77 V ) (b) Assume saturation ⎛ 100x10−6 ⎞⎛ 10 ⎞ 2 3.75 = VGS + 24 x10 ID = VGS + 24 x10 ⎜ ⎟⎜ ⎟(VGS −1) 2 ⎠⎝ 1 ⎠ ⎝ 3 3 12VGS2 − 23VGS + 8.25 = 0 → VGS = 1.439V and ID = 96.4 μA VDS = 12 − 36x10 3 ID = 8.53V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 24 x10 3 ID + VGS = 3.75V which is correct. Q − point : (96.4 μA, 8.53 V ) 4.86 10kΩ 12V = 3.75V | Assume saturation 10kΩ + 22kΩ ⎛ 100x10−6 ⎞⎛ 20 ⎞ 2 3.75 = VGS + 2.4 x10 3 ID = VGS + 24 x10 3⎜ ⎟⎜ ⎟(VGS −1) 2 ⎠⎝ 1 ⎠ ⎝ VGG = 2.4VGS2 − 3.8VGS + 1.35 = 0 → VGS = 1.882V and ID = 778μA VDS = 12 − 3.6x10 3 ID = 9.20V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 2.4 x10 3 ID + VGS = 3.75V which is correct. Q − point : (778 μA, 9.20 V ) 101 4.87 1MΩ 12V = 3.75V | Assume saturation 1MΩ + 2.2MΩ ⎛ 100x10−6 ⎞⎛ 5 ⎞ 2 3.75 = VGS + 2.4 x10 3 ID = VGS + 2.4 x10 5⎜ ⎟⎜ ⎟(VGS −1) 2 ⎠⎝ 1 ⎠ ⎝ VGG = 60VGS2 −119VGS + 56.25 = 0 → VGS = 1.206V and ID = 10.6μA VDS = 12 − 3.6x10 5 ID = 8.18V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 2.4 x10 5 ID + VGS = 3.75V which is correct. Q − point : (10.6 μA, 8.18 V ) 4.88 100kΩ 15V = 4.69V | Assume Saturation 100kΩ + 220kΩ ⎛ 100x10−6 ⎞⎛ 5 ⎞ 2 4.69 = VGS + 24 x10 3 ID = VGS + 24 x10 3⎜ ⎟⎜ ⎟(VGS −1) 2 ⎠⎝ 1 ⎠ ⎝ (a) VGG = 6VGS2 −11VGS + 1.31 = 0 → VGS = 1.705V and ID = 124 μA VDS = 15 − 36x10 3 ID = 10.5 V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 24 x10 3 ID + VGS = 4.68V which is correct. Q − point : (124 μA, 10.5 V ) (b) VGG = 4.69V | Assume Saturation ⎛ 100x10−6 ⎞⎛ 10 ⎞ 2 4.69 = VGS + 24 x10 3 ID = VGS + 24 x10 3⎜ ⎟⎜ ⎟(VGS −1) 2 ⎝ ⎠⎝ 1 ⎠ 12VGS2 − 23VGS + 7.31 = 0 → VGS = 1.514V and ID = 132 μA VDS = 15 − 36x10 3 ID = 10.3 V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 24 x10 3 ID + VGS = 4.68V which is correct. Q − point : (132 μA, 10.3 V ) 4.89 200kΩ 12V = 3.81V | Assume Saturation 200kΩ + 430kΩ ⎛ 100x10−6 ⎞⎛ 5 ⎞ 2 3.81 = VGS + 47x10 3 ID = VGS + 47x10 3 ⎜ ⎟⎜ ⎟(VGS −1) 2 ⎝ ⎠⎝ 1 ⎠ (a) VGG = 23.5VGS2 − 45VGS + 15.88 = 0 → VGS = 1.448V and ID = 50.3 μA VDS = 12 − 71x10 3 ID = 8.43 V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 47x10 3 ID + VGS = 3.81V which is correct. Q − point : (50.3 μA, 8.43 V ) 102 (b) VGG = 3.81V | Assume Saturation ⎛ 100x10−6 ⎞⎛ 15 ⎞ 2 3.81 = VGS + 47x10 ID = VGS + 47x10 ⎜ ⎟⎜ ⎟(VGS −1) 2 ⎝ ⎠⎝ 1 ⎠ 3 3 70.5VGS2 −139VGS + 62.88 = 0 → VGS = 1.269V and ID = 54.3 μA VDS = 12 − 71x10 3 ID = 8.15 V | VDS > VGS − VTN Saturation is correct. Checking : VGG = 47x10 3 ID + VGS = 3.82V which is correct. Q − point : (54.3 μA, 8.15 V ) 4.90 (a) Setting KP = 500U, VTO = 1, and GAMMA = 0 yields ID = 89.6 μA, VGS = 1.60 V and VDS = 8.77 V 4 (a) Setting KP = 1000U, VTO = 1, and GAMMA = 0 yields ID = 96.3 μA, VGS = 1.44 V and VDS = 8.53 V 4 4.91 (a) Setting KP = 500U, VTO = 1, and GAMMA = 0 yields ID = 124 μA, VGS = 1.71 V and VDS = 10.5 V 4 (a) Setting KP = 1000U, VTO = 1, and GAMMA = 0 yields ID = 132 μA, VGS = 1.51 V and VDS = 10.2 V 4 4.92 (a) Setting KP = 500U, VTO = 1, and GAMMA = 0 yields ID = 50.2 μA, VGS = 1.45 V and VDS = 8.43 V 4 (a) Setting KP = 1000U, VTO = 1, and GAMMA = 0 yields ID = 54.1 μA, VGS = 1.27 V and VDS = 8.16 V 4 4.93 (300 kΩ, 700 kΩ) or (1.2 MΩ, 2.8 MΩ). We normally desire the current in the gate bias network to be much less than ID. We also usually like the parallel combination of R1 and R2 to be as large as possible. 4.94 35x10−6 2 (a) ID = (4 −1−1700ID ) and using the quadratic equation, 2 ID = 134μA. VDS =10 -134 x10−6 (1700 + 38300) = 4.64V 25x10−6 2 (4 − 0.75 −1700ID ) and using the quadratic equation, 2 ID = 116μA. VDS =10 -116x10−6 (1700 + 38300) = 5.36V (b) ID = 103 4.95 (a) Example 4.3 Setting KP = 25U and VTO = 1 yields ID = 34.4 μA, VGS = 2.66 V and VDS = 6.08 V 4 Results agree with hand calculations (b) Example 4.4 Setting KP = 25U and VTO = 1 yields ID = 99.2 μA, VGS = 3.82 V and VDS = 6.03 V 4 Results are almost identical to hand calculations 4.96 K n' = 100μA /V 2 | VTN = 0.75V | Choose VDS = VR D = VR S = 4V and VGS − VTN = 1V RS = 4 4.1 = 40kΩ ⇒ 39kΩ and VR S = 3.9V | RD = = 41kΩ ⇒ 43kΩ 100μA 100μA VGS − VTN = 2ID 2I W 2 = 1V and K n = D2 = 200μA /V 2 ⇒ = | Kn 1V L 1 VG = VS + VGS = 3.9 + 1+ 0.75 = 5.65V 5.65V = ⎛ 12V ⎞ R1 R R ⎛ 12V ⎞ 12V | 5.65V = 1 2 ⎜ ⎟ = 530kΩ ⇒ 560kΩ ⎟ | R2 = 250kΩ⎜ ⎝ 5.65V ⎠ R1 + R2 R1 + R2 ⎝ R2 ⎠ 5.65V = R1 12V ⇒ R1 = 500kΩ ⇒ 510kΩ R1 + 560kΩ R1 = 510kΩ, R2 = 560kΩ, RS = 39kΩ, RD = 43kΩ, W 2 = L 1 4.97 K n' = 100μA /V 2 | VTN = 0.75V | Choose VDS = VR D = VR S = 3V and VGS − VTN = 1V 3 3 = 12kΩ | RD = = 12kΩ 0.25mA 0.25mA 2ID 2I W 5 VGS − VTN = = 1V and K n = D2 = 500μA /V 2 ⇒ = Kn 1V L 1 RS = VG = VS + VGS = 3 + 1+ 0.75 = 4.75V 4.75V = ⎛ 9V ⎞ R1 R R ⎛ 9V ⎞ 9V | 4.75V = 1 2 ⎜ ⎟ | R2 = 250kΩ⎜ ⎟ = 473kΩ ⇒ 470kΩ ⎝ 4.75V ⎠ R1 + R2 R1 + R2 ⎝ R2 ⎠ 4.75V = R1 9V ⇒ R1 = 525kΩ ⇒ 510kΩ R1 + 470kΩ R1 = 510kΩ, R2 = 470kΩ, RS = 12kΩ, RD = 12kΩ, 104 W 5 = L 1 4.98 K n' = 100μA /V 2 | VTN = 0.75V | Choose VDS = VR D = VR S = 5V and VGS − VTN = 1V 5 5 = 10kΩ | RD = = 10kΩ 0.5mA 0.5mA 2ID 2I W 10 VGS − VTN = = 1V and K n = D2 = 1mA /V 2 ⇒ = Kn 1V L 1 RS = VG = VS + VGS = 5 + 1+ 0.75 = 6.75V 6.75V = ⎛ 15V ⎞ R1 R R ⎛ 15V ⎞ 15V | 6.75V = 1 2 ⎜ ⎟ = 1.33MΩ ⇒ 1.5MΩ ⎟ | R2 = 600kΩ⎜ ⎝ 6.75V ⎠ R1 + R2 R1 + R2 ⎝ R2 ⎠ R1 15V ⇒ R1 = 1.23MΩ ⇒ 1.2MΩ R1 + 1.5MΩ W 10 R1 = 1.2MΩ, R2 = 1.5MΩ, RS = 10kΩ, RD = 10kΩ, = L 1 6.75V = 4.99 ⎛10−3 ⎞ 2 Assume Saturation. For IG = 0, VGS = −10 4 ID = −10 4 ⎜ ⎟(VGS + 5) ⎝ 2 ⎠ 5VGS2 + 51VGS + 125 = 0 ⇒ VGS = −4.10 V and ID = 410 μA VDS = 15 −15000ID = 8.85 V | VDS > VGS − VTN so saturation is ok. Q - Point : (410μA, 8.85V) 4.100 ⎛ 6x10−4 ⎞ 2 Assume Saturation. For IG = 0, VGS = −27x10 3 ID = −27x10 4 ⎜ ⎟(VGS + 4 ) ⎝ 2 ⎠ 8.1VGS2 + 65.8VGS + 129.6 = 0 ⇒ VGS = −3.36 V and ID = 124 μA VDS = 12 − 78000ID = 2.36 V | VDS > VGS − VTN so saturation is ok. Q - Point : (124 μA, 2.36V) 4.101 Kn = 1 mA/V 2 RD V TN = -5 V + V GS RG VDD ID IG = 0 - + 5V - + 15 V R S 105 ⎛ 1mA/V 2 ⎞ 2 Assume Saturation. IG = 0. 250μA = ⎜ ⎟(VGS + 5) 2 ⎠ ⎝ 0.25mA 4.29V = −4.29V | RS = = 17.2kΩ ⇒ 18kΩ 0.5mA 0.25mA 15 − 5 − 4.29 V VDS = 15 − ID (RD + RS ) ⇒ RD = = 22.88kΩ ⇒ 24kΩ 0.25 mA RG is arbitrary but normally fairly large. Choose RG = 510 kΩ. VGS = −5 + 4.102 + 5V R R D 2 + VDD + 5V + R1 R S 15 V 5V - Assume Saturation. IG = 0. Assume power supply is split in thirds: VDS = VR D = VRS = 5V Kn 2 VTN and this will require VGS > 0. 2 ⎛ 0.25mA/V 2 ⎞ 5V 2 RS = = 2.5kΩ ⇒ 2.4kΩ and VRS will be 4.8 V | 2mA = ⎜ ⎟(VGS + 2) 2 2mA ⎝ ⎠ Note that although, this is a depletion - mode device, I D exceeds VGS = −2 + 2mA = +2.00V | VG = VS + VGS = 4.8 + 2 = 6.8V 0.125mA R1 ⇒ R1 = 680 kΩ and R2 = 820 kΩ is one convenient possibility. R1 + R2 Another is R1 = 68 kΩ and R2 = 82 kΩ. Both choices have IR 2 << I D . 6.8 = 15 RD = 106 (15 − 5 − 4.8)V 2mA = 2.60kΩ ⇒ 2.70 kΩ. 4.103 (a) The transistor is saturated by connection. VGS = 12 −10 5 ID and ID = 100x10−6 ⎛ 10 ⎞⎛ A ⎞ 2 ⎜ ⎟⎜ 2 ⎟(VGS − 0.75V ) ⎝ 1 ⎠⎝ V ⎠ 2 50VGS2 − 74VGS + 16.13 = 0 ⇒ VGS = 1.214V, − 0.266V ⇒ VGS = 1.214 V since VGS must 100x10−6 ⎛10 ⎞⎛ A ⎞ 2 ⎜ ⎟⎜ 2 ⎟(1.214 − 0.75V ) ⎝ 1 ⎠⎝ V ⎠ 2 12 −1.21 ID = 104μA | Checking : ID = = 108 μA | Q - Point : (108 μA,1.21 V) 10 5 exceed the threshold voltage. | ID = 7 (b) Using KVL, VDS = 10 IG +VGS. But, since IG = 0, VGS = VDS. Also VTN = 0.75 V > 0, so the transistor is saturated by connection. +12 V 10 W = L 1 ID = 10 M Ω 330 k Ω IDS I VDS + V GS - - VGS = 12 − 330kΩ(ID + IG ) −10MΩ(IG ) but I G = 0 VGS = 12 − 330kΩ(ID ) + G ⎛100 μA ⎞⎛10 ⎞ K n' W 2 2 ⎟(VGS − 0.75) (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L ⎛ 1.00x10−3 A ⎞ 2 VGS = 12 − (3.30x10 5 )⎜ V − 0.75) 2 ⎟( GS 2 V ⎠ ⎝ 165VGS2 − 246.5VGS + 80.81 = 0 yields VGS = 1.008V , 0.486V VGS must be 1.008 V since 0.486 V is below threshold. ⎛100 μA ⎞ 10 2 ID = ⎜ (1.008 − 0.75) = 33.3 μA and VDS = VGS 2⎟ ⎝ 2 V ⎠1 Q-Point: (33.3 μA, 1.01 V) Checking: ID =(12-1.01)V/330kΩ = 33.3 μA. 4 4.104 (a) The transistor is saturated by connection. VGS = 12 −10 5 ID and ID = 100x10−6 ⎛ 20 ⎞⎛ A ⎞ 2 ⎜ ⎟⎜ 2 ⎟(VGS − 0.75V ) ⎝ 1 ⎠⎝ V ⎠ 2 100VGS2 −149VGS + 44.25 = 0 ⇒ VGS = 1.08V, 0.410V ⇒ VGS = 1.08 V since VGS must exceed the threshold voltage. ID = Checking : ID = 100x10−6 ⎛ 20 ⎞⎛ A ⎞ 2 ⎜ ⎟⎜ 2 ⎟(1.08 − 0.75V ) = 109μA ⎝ 1 ⎠⎝ V ⎠ 2 12 −1.08 = 109 μA | Q - Point : (109 μA, 1.08 V) 10 5 7 (b) Using KVL, VDS = 10 IG +VGS. But, since IG = 0, VGS = VDS. Also VTN = 0.75 V > 0, so the transistor is saturated by connection. 107 +12 V 10 W = L 1 ID = 10 M Ω 330 k Ω IDS I G V GS - VGS = 12 − 330kΩ(ID + IG ) −10MΩ(IG ) but IG = 0 VGS = 12 − 330kΩ(ID ) + VDS + ⎛100 μA ⎞⎛ 20 ⎞ K n' W 2 2 ⎟(VGS − 0.75) (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L - ⎛ A⎞ 2 VGS = 12 − (3.30x10 5 )⎜10−3 2 ⎟(VGS − 0.75) ⎝ V ⎠ 3.3VGS2 − 4.94VGS + 1.736 = 0 yields VGS = 0.933V, 0.564V VGS must be 0.933 V since 0.564 V is below threshold. ⎛100 μA ⎞ 20 12 − 0.933 2 ID = ⎜ V = 33.5μA (0.933 − 0.75) = 33.5 μA Checking : 2⎟ ⎝ 2 V ⎠ 1 330kΩ and VDS = VGS : Q-Point: (33.5 μA, 0.933 V) 4.105 (a) Assume saturation : ID = ⎛100 μA ⎞⎛ 10 ⎞ K n' W 2 2 ⎟(VGS − 0.75) (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L VGS = 15 − 330kΩ(ID + IG ) −10MΩ(IG ) but I G = 0 VGS = 15 − 330kΩ(ID ) and VGS = VDS so saturation regioin operation is correct ⎛ 10−3 A ⎞ 2 VGS = 15 − (3.30x10 5 )⎜ V − 0.75) 2 ⎟( GS ⎝ 2 V ⎠ 3.30VGS2 − 4.93VGS + 1.556 = 0 yields VGS = 1.041V, 0.453V ⎛100 μA ⎞⎛ 10 ⎞ 15 −1.041 2 ID = ⎜ V = 42.3μA ⎟(1.041− 0.75) = 42.3μA | Checking : ID = 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 330kΩ Q − Point : (42.3 μA, 1.04 V) (b) Assume saturation ID = ⎛100 μA ⎞⎛ 25 ⎞ K n' W 2 2 ⎟(VGS − 0.75) (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L VGS = 15 − 330kΩ(ID + IG ) −10MΩ(IG ) but I G = 0 VGS = 15 − 330kΩ(ID ) and VGS = VDS so saturation region operation is correct. ⎛ 2.50x10−3 A ⎞ 2 V − 0.75) VGS = 15 − (3.30x10 5 )⎜ 2 ⎟( GS V ⎠ 2 ⎝ 8.25VGS2 −12.355VGS + 4.341 = 0 yields VGS = 0.9345V, 0.563V ⎛100 μA ⎞⎛ 25 ⎞ 15 − 0.9345 2 V = 42.6μA ID = ⎜ ⎟(0.9345 − 0.75) = 42.6μA | Checking : ID = 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 330kΩ Q - Point : 108 (42.6 μA, 0.935 V) 4.106 (a) Asssume saturation ID = ⎛100 μA ⎞⎛10 ⎞ K n' W 2 2 ⎟(VGS − 0.75) (VGS − VTN ) = ⎜ 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 2 L VGS = 12 − 470kΩ(ID + IG ) −10MΩ(IG ) but IG = 0 VGS = 12 − 470kΩ(ID ) and VGS = VDS so saturation region operation is correct. ⎛ 10−3 A ⎞ 2 VGS = 12 − (4.70x10 5 )⎜ V − 0.75) 2 ⎟( GS ⎝ 2 V ⎠ 4.70VGS2 − 7.03VGS + 2.404 = 0 yields VGS = 0.9666V, 0.529V ⎛100 μA ⎞⎛ 10 ⎞ 12 − 0.967 2 ID = ⎜ = 23.5μA ⎟(0.9666 − 0.75) = 23.5μA | Checking : ID = 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ 470kΩ Q - Point : (23.5 μA, 0.967 V) (b) Since the current in RG is zero, the drain current is independent of RG. 4.107 (a) Create an M-file: function f=bias(id) vtn=1+0.5*(sqrt(22e3*id)-sqrt(0.6)); f=id-(25e-6/2)*(6-22e3*id-vtn)^2; fzero('bias',1e-4) yields ans = 8.8043e-05 (b) Modify the M-file: function f=bias(id) vtn=1+0.75*(sqrt(22e3*id)-sqrt(0.6)); f=id-(25e-6/2)*(6-22e3*id-vtn)^2; fzero('bias',1e-4) yields ans = 8.3233e-05 4.108 Using a spreadsheet similar to Table 4.2 yields: (a) 88.04 μA, (b) 83.23 μA. 4.109 100kΩ 12V = 3.75V | Assume saturation 100kΩ + 220kΩ 2ID VTN = 1+ 0.6 24 x10 3 ID + 0.6 − 0.6 | VGS = VTN + 5x10−4 3.75 − VGS ID = | Solving iteratively yields ID = 73.1μA with VTN = 1.460V 24kΩ V = 12V − ID (24kΩ + 12kΩ) = 9.37 V Transistor is saturated. Q - Point : (73.1 μA, 9.37 V) VGG = ( ) 109 4.110 VGG = 100kΩ 12V = 3.75V | Assume saturation 100kΩ + 220kΩ (a) VTN = 1+ 0.75( 24 x10 3 ID + 0.6 − 0.6 )| VGS = VTN + 2ID 5x10−4 3.75 − VGS | Solving iteratively yields ID = 69.7μA with VTN = 1.550V 24kΩ = 12V − ID (24kΩ + 12kΩ) = 9.49 V The transistor is saturated. Q - Point : (69.7 μA, 9.49 V) ID = VDS (b) VTN = 1+ 0.6( 24 x10 3 ID + 0.6 − 0.6 )| VGS = VTN + 2ID 5x10−4 3.75 − VGS | Solving iteratively yields ID = 73.1μA with VTN = 1.460V 24kΩ V = 12V − ID (24kΩ + 24kΩ) = 8.49 V The transistor is saturated. Q - Point : (73.1 μA, 8.49 V) ID = 4.111 (a) γ = 0.6 (b) γ = 0.75 (c ) γ = 0.6 VTN = 1.46 V VTN = 1.55 V VTN = 1.46 V ID = 73.1 μA ID = 69.7 μA ID = 73.1 μA VDS = 9.37 V VDS = 9.49 V VDS = 8.49 V These results all agree with the hand calculations. (They should - they are all solving the same sets of equations.) 4.112 (a) γ = 0 VTN = 1.00 V ID = 50.2 μA VDS = 8.43 V γ = 0.5 VTN = 1.42 V (b) γ = 0 VTN = 1.00 V γ = 0.5 VTN = 1.44 V ID = 42.2 μA VDS = 9.01 V ID = 54.1 μA VDS = 8.16 V ID = 45.2 μA VDS = 8.79 V The γ = 0 values agree with the hand calculations in the original problem. Including body effect in the simulations reduces the Q-point current by approximately 15%. Although this may sound large, it is within the error that will be introduced by the use of 5% resistors and typical device tolerances. So, we normally omit γ in our hand calculations, and then refine the results using SPICE. 4.113 (a) γ = 0 VTN = 1.00 V ID = 89.6 μA VDS = 8.77 V γ = 0.5 VTN = 1.39 V (b) γ = 0 VTN = 1.00 V γ = 0.5 VTN = 1.41 V ID = 75.5 μA VDS = 9.28 V ID = 96.3 μA VDS = 8.53 V ID = 80.8 μA VDS = 9.09 V The γ = 0 values agree with the hand calculations in the original problem. Including body effect in the simulations reduces the Q-point current by approximately 15%. Although this may sound 110 large, it is within the error that will be introduced by the use of 5% resistors and typical device tolerances. So, we normally omit γ in our hand calculations, and then refine the results using SPICE. 4.114 γ =0 γ = 0.5 VTN = 1.00 V VTN = 1.35 V ID = 778 μA ID = 661 μA VDS = 9.20 V VDS = 9.62 V The γ = 0 values agree with the hand calculations in the original problem. Including body effect in the simulations reduces the Q-point current by approximately 15%. Although this may sound large, it is within the error that will be introduced by the use of 5% resistors and typical device tolerances. So, we normally omit γ in our hand calculations, and then refine the results using SPICE. 4.115 γ =0 γ = 0.5 VTN = 1.00 V VTN = 1.45 V ID = 10.5 μA ID = 9.18 μA VDS = 8.03 V VDS = 8.69 V The γ = 0 values agree with the hand calculations in the original problem. Including body effect in the simulations reduces the Q-point current by approximately 15%. Although this may sound large, it is within the error that will be introduced by the use of 5% resistors and typical device tolerances. So, we normally omit γ in our hand calculations, and then refine the results using SPICE. 4.116 (a) Both transistors are saturated by connection and the two drain currents must be equal. K K 2 2 ID1 = n1 (VGS1 − VTN1 ) and ID 2 = n 2 (VGS 2 − VTN 2 ) 2 2 But since the transistors are identical, ID1 = ID2 requires VGS1 = VGS2 = VDD/2 = 2.5V. 100x10−6 ⎛ 20 ⎞ 2 ID1 = ID 2 = ⎜ ⎟(2.5 −1) = 2.25 mA ⎝1⎠ 2 (b) For this case, the same arguments hold, and VGS1 = VGS2 = VDD/2 = 5V. 100x10−6 ⎛ 20 ⎞ 2 ID1 = ID 2 = ⎜ ⎟(5 −1) =16.0 mA ⎝1⎠ 2 . (c) For this case, the threshold voltages will be different due to the body-effect in the upper transistor. The drain currents must be the same, but the gate-source voltages will be different: VGS1 = VTN1 + VTN1 =1V 2ID 2ID ; VGS 2 = VTN 2 + ; VGS1 + VGS 2 = 5V . Kn Kn ( VTN 2 = 1+ 0.5 VGS1 + 0.6 − 0.6 ) 111 Combining these equations yields ( ) 5 - 2VGS1 − 0.5 VGS1 + 0.6 − 0.6 = 0 ⇒ VGS1 = 2.27V ; VGS 2 = 5 − VGS1 = 2.73V ID 2 = ID1 = 100x10−6 ⎛ 20 ⎞ 2 ⎜ ⎟(2.27 −1) = 1.61 mA. ⎝1⎠ 2 ( ) Checking : VTN 2 = 1+ 0.5 2.27 + 0.6 − 0.6 = 1.46V ID 2 = 100x10−6 ⎛ 20 ⎞ 2 ⎜ ⎟(2.73 −1.46) = 1.61 mA. ⎝1⎠ 2 4.117 If we assume saturation, we find ID = 234 μA and VDS = 0.65 V, and the transistor is not saturated. Assuming triode region operation, VGS = 10 − 2x10 4 ID | VDS = 10 − 4 x10 4 ID μA ⎛ 2 ⎞⎛ 10 − 4 x10 4 ID ⎞ 4 ID = 100 2 ⎜ ⎟⎜10 − 2x10 4 ID −1− ⎟(10 − 4 x10 ID ) ⎝ ⎠ 2 V 1 ⎝ ⎠ Collecting terms : 16.5x10 4 ID = 40 → ID = 242 μA VDS = 10 − 4 x10 4 (2.42x10−4 )= 0.320V | Q - Pt : (242 μA, 0.320V ) Checking the operating region : VGS − VTN = 4.16V > VDS and the triode region assumption is correct. Checking : ID = 10 − 0.32 V = 242μA 40kΩ 4.118 If we assume saturation, we find an inconsistent answer. Assuming triode region operation, VGS = 10 − 2x10 4 ID | VDS = 10 − 3x10 4 ID μA ⎛ 4 ⎞⎛ 10 − 3x10 4 ID ⎞ 4 ID = 100 2 ⎜ ⎟⎜10 − 2x10 4 ID −1− ⎟(10 − 3x10 ID ) 2 V ⎝ 1 ⎠⎝ ⎠ Collecting terms : 1.5x10 8 ID2 −1.725x10 5 ID + 40 = 0 → ID = 322μA VDS = 10 − 3x10 4 (3.22x10−4 )= 0.340V | Q - Pt : (322 μA, 3.18 V ) Checking the operating region : VGS − VTN = 2.56V > VDS and the triode region assumption is correct. Checking : ID = 112 10 − 0.34 V = 322μA 30kΩ 4.119 For (a) and (b), γ = 0. The transistor parameters are identical so 3VGS = 15V or VGS = 5V. ⎛ 20 ⎞ 1 2 (a) ID = (100x10−6 )⎜ ⎟(5 − 0.75) = 18.1 mA ⎝1⎠ 2 ⎛ 50 ⎞ 1 2 (b) ID = (100x10−6 )⎜ ⎟(5 − 0.75) = 45.2 mA ⎝1⎠ 2 (c) Now we have three different threshold voltages and need an iterative solution. Using MATLAB: function f=Prob112(id) gamma=0.5; vgs1=.75+sqrt(2*id/2e-3); vtn2=0.75+gamma*(sqrt(vgs1+0.6)-sqrt(0.6)); vgs2=vtn2+sqrt(2*id/2e-3); vtn3=0.75+gamma*(sqrt(vgs1+vgs2+0.6)-sqrt(0.6)); vgs3=vtn3+sqrt(2*id/2e-3); f=15-vgs1-vgs2-vgs3; fzero('Prob112',1e-4) --> ans = 0.0130 ID = 13.0 mA 4.120 W 20 = VTN = 0.75 V ID = 18.1 mA VDS = 5.00 V 1 L W 50 = VTN = 0.75 V ID = 45.2 mA VDS = 5.00 V (b) γ = 0 L 1 W 20 = VTN 3 = 1.95 V ID 3 = 13.0 mA VDS 3 = 5.56 V (b) γ = 0.5 L 1 VTN 2 = 1.48 V ID 2 = 13.0 mA VDS 2 = 5.09 V VTN1 = 0.75 V ID1 = 13.0 mA (a) γ = 0 VDS1 = 4.36 V Results are identical to calculations in Prob. 4.119 4.121 For VGS = 5 V and VDS = 0.5 V, the transistor will be in the triode region. (5 − 0.5)V = 54.88μA | 54.88x10−6 = 100x10−6⎛ W ⎞⎛5 − 0.75 − 0.5 ⎞0.5 | W = 0.274 = 1 ID = ⎜ ⎟⎜ ⎟ ⎝ L ⎠⎝ 2 ⎠ L 1 3.64 82kΩ 4.122 For VGS = 3.3 V and VDS = 0.25 V, the transistor will be in the triode region. (3.3 − 0.25)V = 16.94 μA | 16.94 x10−6 = 100x10−6⎛ W ⎞⎛ 3.3 − 0.75 − 0.25 ⎞0.25 | W = 0.280 = 1 ID = ⎜ ⎟⎜ ⎟ ⎝ L ⎠⎝ 2 ⎠ L 1 3.57 180kΩ 113 4.123 (a) The transistor is saturated by connection. For this circuit, VGS = VDD + ID R = −15 + 75000ID 4 x10−5 ⎛ 1⎞ 2 ID = ⎜ ⎟(−15 + 75000ID + 0.75) ⇒ 153 μA 2 ⎝ 1⎠ VGS = −15 + 75000ID = −3.525V VDS = VGS = −3.525V | Q - point : (153 μA,−3.53 V ) (b) Here the transistor has VGS = -15 V, a large value, so the transistor is most likely operating in the triode region. ⎛ VDS − (−15) V ⎞ = 4 x10−5 ⎜ −15 − (−0.75) − DS ⎟VDS ⇒ VDS = −0.347 V and ID = 195 μA. ⎝ 75000 2 ⎠ 15 − 0.347 V = 195μA Q - point : (195 μA,-0.347 V ) Checking : ID = 785kΩ Checking the region of operation: VDS = −0.347V > VGS − VTP = −15 + 0.75 = −14.25V ID = Triode region is correct 4.124 Set W=1U L=1U KP=40U VTO=-0.75 GAMMA=0 Results are almost identical to hand calculations for both parts. 4.125 (a) IDP = IDN , and both transistors are saturated by connection. 10 = -VGSP + VGSN 1 ⎛ 100μA ⎞⎛ 20 ⎞ 1 ⎛ 40μA ⎞⎛ 20 ⎞ 2 2 ⎜ 2 ⎟⎜ ⎟(−10 + VGSN + 0.75) = ⎜ ⎟⎜ ⎟(VGSN − 0.75) 2 2 ⎝ V ⎠⎝ 1 ⎠ 2 ⎝ V ⎠⎝ 1 ⎠ (9.25 − VGSN ) = 2.5 (VGSN − 0.75) → VGSN = 4.04V | VGSP = −5.96V IDP = IDN = 10.8 mA | VO = VGSN = 4.04V (b) Everything is the same except the currents scale by 80/20: IDP = IDN = 43.2 mA 4.126 For (a) and (b), γ = 0. The transistor parameters are identical so -3VGS = 15V or VGS = -5V. 1 40 2 40x10−6 ) (−5 + 0.75) = 14.4 mA ( 2 1 1 75 2 (b) ID = (40x10−6 ) (−5 + 0.75) = 27.1 mA 2 1 (a) ID = (c) Now we have three different threshold voltages and need an iterative solution. Using MATLAB: function f=PMOSStack(id) gamma=0.5; 114 vsg1=.75+sqrt(2*id/1.6e-3); vtp2=-0.75-gamma*(sqrt(vsg1+0.6)-sqrt(0.6)); vsg2=-vtp2+sqrt(2*id/1.6e-3); vtp3=-0.75-gamma*(sqrt(vsg1+vsg2+0.6)-sqrt(0.6)); vsg3=-vtp3+sqrt(2*id/1.6e-3); f=15-vsg1-vsg2-vsg3; fzero('PMOSStack',1e-1) --> ans = 0.0104 ID = 10.4 mA. 4.127 (a) W=40U L=1U KP=40U VTO=-0.75 GAMMA=0 (b) W=75U L=1U KP=40U VTO=-0.75 GAMMA=0 (c) W=75U L=1U KP=40U VTO=-0.75 GAMMA=0.5 Results agree with hand calculations. 4.128 4V = 2mA. For ID = 0,VDS = −4V . (VSD = +4V ) 2kΩ 300kΩ VGS = VEQ = −4V = −3V (VSG = +3V ) 300kΩ + 100kΩ From the graph, the transistor is operating below pinchoff in the linear region. For VDS = 0, ID = 5000 VSG = 5 V Drain Current ( μA) 4000 3000 V SG =4V 2000 Q-point VSG = 3 V 1000 V SG =2V 0 -1000 -1 0 1 2 3 4 Source-Drain Voltage (V) 5 6 Q-point: (1.15 mA, 1.7V) 115 PMOS Transistor Output Characteristics 5000 V GS = -5 V Drain Current ( μA) 4000 3000 VGS = -4 V 2000 V GS = -3 V 1000 V GS = -2 V 0 -1000 -1 0 1 2 3 4 Source-Drain Voltage (V) 116 5 6 4.129 (a) VGG = ⎛ 4 x10−5 ⎞ 20 15V 2 = 7.5V | 7.5 = 10 5 ID - VGS | 7.5 = 10 5 ⎜ ⎟ (VGS + 0.75) - VGS 2 ⎝ 2 ⎠ 1 4VGS2 + 5.9VGS −1.5 = 0 → VGS = −1.148V and ID = 63.5μA VDS = −(15 − (100kΩ + 50kΩ)ID ) = −5.47V | Q - point : (59.78 μA,−5.47 V ) (b) For saturation, VDS ≤ VGS − VTP or VSD ≥ VSG + VTP 15 − (100kΩ + R)ID ≥ 7.5 −100kΩID − 0.75 → R ≤ 130 kΩ 4.130 Setting W=20U, L=1U, LEVEL=1, KP=40U, VTO=-0.75 yields results identical to the previous problem. 4.131 (a) Using MATLAB: function f=bias4(id) gamma=0.5; vbs=1e5*id; vgs=-7.5+vbs; vtp=-0.75-gamma*(sqrt(vbs+0.6)-sqrt(0.6)); f=id-(8e-4/2)*(vgs-vtp)^2; fzero('bias4',4e-5) --> ans = 5.5278e-05 --> ID = 55.3 μA VDS = -15 + (100kΩ+R) ID (b) VDS ≤ VGS - VTP | -15 + (100kΩ+R)ID ≤ -1.972 + 1.600 | R ≤ 164 kΩ 4.132 Setting W=20U, L=1U, LEVEL=1, KP=40U, VTO=-0.75 GAMMA=0.5 yields results identical to the previous problem. 4.133 (a) V DD R V + GS - S VDS G D + I SD The arrow identifies the transistor as a PMOS device. Since γ = 0, we do not need to worry about body effect: VTP = VTO. Since VDS = VGS, and VTP < 0, the transistor is saturated. 117 K 'p W 2 ID = (VGS − VTP ) and - VGS = 12 −105 ID 2 L ⎛ 4 x10−5 ⎞⎛ 10 ⎞ 2 -VGS = 12 −10 5 ⎜ ⎟⎜ ⎟(VGS − (−0.75)) ⎝ 2 ⎠⎝ 1 ⎠ 20VGS2 + 29VGS − 0.75 = 0 yields VGS = −1.475V,+0.0255V We require VGS < VTP = -0.75 V for the transistor to be conducting so 2 4 x10−5 ⎛ 10 ⎞ A VGS = −1.475V and ID = ⎜ ⎟ 2 (−1.475 − (−0.75)) = 105 μA 2 ⎝ 1 ⎠V Since VDS = VGS, the Q-point is given by: Q-Point = (105 μA, -1.475 V). (b) Using MATLAB for the second part (Set gamma = 0 for part (a)): function f=bias2(id) gamma=1.0; vgs=-12+1e5*id; vsb=-vgs; vtp=-0.75-gamma*(sqrt(vsb+0.6)-sqrt(0.6)); f=id-5e-5*(vgs-vtp)^2; fzero('bias2',1e-4) --> ans = 9.5996e-05 and Q-Point = (96.0 μA, 2.40 V). 4.134 VGG −5 ⎞ ⎛ 2 15V 40 4 4 4x10 = = 7.5V | 7.5 = 5x10 I D - VGS | 7.5 = 5x10 ⎜ ⎟ (VGS + 0.75) - VGS 2 ⎝ 2 ⎠ 1 890VGS2 + 119VGS − 30 = 0 → VGS = −1.166V and I D = 138 μA ( ) VDS = − 15 − (R + 50kΩ)I D = −5V → R = 22.3 kΩ 4.135 VGG = I D = 138 μA ⎛ 4x10−5 ⎞ 40 2 15V = 7.5V | 7.5 = 15 - 5x10 4 I D + VGS | 7.5 = 5x10 4 ⎜ ⎟ (VGS − VTP ) - VGS 2 ⎝ 2 ⎠ 1 ( VTP = −0.75 − 0.5 5x10 4 I D + 0.6 − 0.6 ) Solving iteratively yields I D = 111 μA with VTP = −1.60V ( ) VDS = − 15 − (R + 50kΩ)I D = −5V → R = 40.1 kΩ 118 4.136 510kΩ = 9.81V | 9.81 = 15 -105 I D + VGS 510kΩ + 270kΩ ⎛ 4x10−5 ⎞ 20 2 5.19 = 105⎜ ⎟ (VGS + 0.75) − VGS ⎝ 2 ⎠ 1 (a) VGG = 15V 40VGS2 + 59VGS + 17.31 = 0 → VGS = −1.071 V and I D = 41.2 μA (b) For saturation, VDS ≤ VGS − VTP −15 + (100kΩ + R)I D ≤ −1.071+ 0.75 → R ≤ 256 kΩ 4.137 510kΩ = 9.81V | 9.81 = 15 -105 I D + VGS 510kΩ + 270kΩ ⎛ 4x10−5 ⎞ 20 2 5 5.19 = 105 ⎜ ⎟ (VGS − VTP ) − VGS | VTP = −0.75 − 0.5 10 I D + 0.6 − 0.6 ⎝ 2 ⎠ 1 (a) VGG = 15V ( ) Solving iteratively yields I D = 35.2 μA with VTP = −1.38 V and VGS = −1.67 V (b) For saturation, VDS ≤ VGS − VTP −15 + (100kΩ + R)I D ≤ −1.67 + 1.38 → R ≤ 318 kΩ 4.138 (a) Assume an equal voltage (5V) split between R D , RS and VDS. We need VDS ≤ VGS − VTP or - 5 ≤ VGS − VTP . Choose VGS − VTP = −2V. Kn = (V GS 2I D − VTP ) 2 = 2mA W 12.5 → = . 4 L 1 VGS = −2 − 0.75 = −2.75V. VEQ = 5 − VGS = 7.75V. 7.75 = 15 R1 15 R1 R2 15 = = 100kΩ. R2 = 193.5kΩ → 200kΩ. R1 + R2 R2 R1 + R2 R2 7.75 = 15 220kΩ R1 → R1 = 214kΩ → 220kΩ. VEQ = 15 = 7.86V 220kΩ + 200kΩ R1 + R2 7.86V − 2.75V 15 − 5 − 5.1 = 5.11kΩ → 5.1kΩ | RD = = 4.9kΩ → 4.7kΩ 1mA 1mA Note that R1 is connected between the gate and + 15 V, and R 2 is connected between RS = the gate and ground. (b) For the NMOS case, choose W/L = 5/1. The resistors now have the same values except R2 is now connected between the gate and +15 V, R1 is connected between the gate and ground, and RD = 15 − 6 − 5.1 = 3.9kΩ 1mA 119 4.139 (a) Assume an equal voltage (3V) split between R D , RS and VDS. We need VDS ≤ VGS − VTP or - 3 ≤ VGS − VTP . Choose VGS − VTP = −1V. Kn = (V GS 2I D = − VTP ) 2 1mA W 25 → = . 1 L 1 VGS = −1− 0.75 = −1.75V. VEQ = 3 − VGS = 4.75V. 4.75 = 9 R1 9 R1 R2 9 = = 1MΩ. R2 = 1.7 MΩ →1.8 MΩ. R1 + R2 R2 R1 + R2 R2 4.75 = 9 2 MΩ R1 → R1 = 2.01MΩ → 2 MΩ | VEQ = 9 = 4.74V 1.8 MΩ + 2 MΩ R1 + R2 4.74V −1.75V 9 −3−3 = 5.97kΩ → 6.2kΩ | RD = = 6.0kΩ → 6.2kΩ 0.5mA 0.5mA Note that R1 is connected between the gate and + 9 V, and R 2 is connected between RS = the gate and ground. R1 = 2 MΩ, R2 = 1.8 MΩ, RS = RD = 6.2kΩ, W / L = 25/1 (b) For the NMOS case, choose W/L = 40/1. The resistors now have the same values except R2 is now connected between the gate and + 9 V, and R1 is connected between the gate and ground. 4.140 ⎛ 40 μA ⎞⎛ 10 ⎞ 4 VGS = 10 4 I D | Assume saturation : I D = ⎜ ⎟ 10 I D − 4 2 ⎟⎜ ⎝ 2 V ⎠⎝ 1 ⎠ ( ) 2 Collecting terms : 108 I D2 − 8.5x10 4 I D + 16 = 0 → I D = 281 μA ( ) VDS = − 15 −10 4 I D = −12.2V | Q - Pt : (281 μA,−12.2 V ) Checking : VGS − VTP = 2 − 4 = −1.19 V | VDS = −12.2 | Saturation is correct. 4.141 ( VGS = 10 4 I D | VTP = 4 − 0.25 VGS + 0.6 − 0.6 ) | ID = Solving these equations iteratively yields I D = 260 μA ( ) 2 4x10−4 VGS − VTP ) ( 2 VDS = − 15 −10 4 I D = −12.4V | Q - Pt : (260 μA,−12.4 V ) 120 4.142 Note: The answers are very sensitive to round-off error and are best solved iteratively using MATLAB, a spreadsheet, HP solver, etc. Hand calculations using the quadratic equation will generally yield poor results. Saturated by connection with VTP = −1 2 4x10−5 ⎛ 10 ⎞ 5 6 11 2 ID = ⎜ ⎟ 3.3x10 I D −12 − (−1) →121− 7.265x10 I D + 1.089x10 I D = 0 2 ⎝1⎠ [ ] I D = 34.6μA, 32.1μA | VDS = 3.3x105 I D −12 = −0.582V ,−1.407V | Q - point : (32.1 μA,−1.41 V ) since the transistor would not be conducting for VGS = −0.582V. 4.143 Note: The answers are very sensitive to round-off error and are best solved iteratively using MATLAB, a spreadsheet, HP solver, etc. Hand calculations using the quadratic equation will generally yield poor results. Saturated by connection with VTP = −3 ⎛ 4x10−5 ⎞⎛ 30 ⎞ 2 5 6 11 2 ID = ⎜ ⎟⎜ ⎟ 3.3x10 I D −12 − (−3) → 81− 5.941x10 I D + 1.089x10 I D = 0 ⎝ 2 ⎠⎝ 1 ⎠ [ ] I D = 27.07μA | VDS = 3.3x105 I D −12 = −3.067V | Q - point : (27.1 μA,−3.07 V ) 4.144 Note: The answers are very sensitive to round-off error and are best solved iteratively using MATLAB, a spreadsheet, HP solver, etc. Hand calculations using the quadratic equation will generally yield poor results. (a) Large VGS − Assume triode region. ⎛ 10 ⎞⎛ V ⎞ | I D = 40x10−6 ⎜ ⎟⎜12 − 0.75 − DS ⎟VDS 2 ⎠ ⎝ 1 ⎠⎝ VDS = 12 − 3.3x105 I D Q − po int : (36.1 μA, 80.6 mV) | VDS < VGS − VTN so triode region is correct. 2 10x10−6 ⎛ 25 ⎞ 5 Saturated by connection : I = b ⎜ ⎟ 3.3x10 I D −12 + 0.75 () D 2 ⎝1⎠ ( Q − point : (32.4μA,-1.32V) (c) V TP ID = ( = −0.75 − 0.5 3.3x105 I D + 0.6 − 0.6 40x10−6 ⎛ 25 ⎞ 5 ⎜ ⎟ 3.3x10 I D −12 − VTP 2 ⎝1⎠ ( ) 2 ) ) ( | VDS = − 12 − 3.3x105 I D ) Q − point : (28.8 μA,-2.49 V) 121 4.145 (a) Kn = μn ID = (b) K ' n Tox (a) C GC ⎥⎝ 2μm ⎠ ⎦ V2 2 864μA ⎛ 4 1 ⎞ | I = ⎜ − ⎟ = 0.972 mA 2 ⎝ 2 2⎠ V | V = 2 ' ' D ( ⎡ 3.9 8.854x10−14 F / cm ⎢ = C WL = ⎢ 20x10−7 cm ⎣ (b) α = 2 " OX ' | CGC = CGC 1 gm 2π CGC | gm = )⎥⎤ 20x10 ( ⎥ −4 ⎦ )( ) cm 10−4 cm = 34.5 fF = 17.3 fF α 4.147 fT = )⎥⎤⎛⎜ 20μm ⎞⎟ = 432 μA 2 432μA 4 −1) = 1.94 mA ( 2 = 2Kn 4.146 ( −14 ⎡ cm2 ⎢ 3.9 8.854x10 F / cm = 500 V −s⎢ L 40x10−7 cm ⎣ εox W ∂iD " W " = KP (VGS − VTP ) = μ pCOX | CGC = COX WL ∂vGS L 1 μp (VGS − VTP ), but (VGS − VTP )< 0 for PMOS transistor. 2π L2 1 μp Since f T should be positive, f T = (VGS − VTP ) 2π L2 fT = 4.148 1 ⎛μ⎞ ⎜ ⎟(VGS − VTN ) 2π ⎝ L2 ⎠ ⎡ ⎤ 1 ⎢400cm2 /V − s ⎥ fTN = (1V )= 6.37 GHz | fTP = 0.4 fTN = 2.55 GHz 2π ⎢ 10−4 cm 2 ⎥ ⎢⎣ ⎥⎦ ⎡ ⎤ 1 ⎢ 400cm 2 /V − s ⎥ (b) fTN = 2π ⎢ −5 2 ⎥(1V )= 637 GHz | fTP = 0.4 fTN = 255 GHz ⎢⎣ 10 cm ⎥⎦ (a) f T 122 = ( ) ( ) 4.149 (a) Kn = μn ID = Tox ( −14 ⎡ cm2 ⎢ 3.9 8.854x10 F / cm = 400 V − s⎢ L 80x10−7 cm ⎣ εox W 345μA 2 (2) = 690μA 2 ( )⎥⎤⎛⎜ 2μm ⎞⎟ = 345 μA 3.9 8.854x10−14 F / cm W (b) I D = C 2 (VGS − VTN )vsat = 80x10−7 cm " ox ⎥⎝ 0.1μm ⎠ ⎦ V2 )⎛⎜ 2x10 cm ⎞ 7 ⎟(2V ) 10 cm / s = 86.3μA 2 ⎠ −4 ⎝ ( ) 4.150 For VGS = 0, ID = 10-22 A. For VTN = 0.5 V and VGS = 0, ID = 10-15 A. 123 CHAPTER 5 5.1 Base Contact = B n-type Emitter = D Collector Contact = A n-type Collector = F Emitter Contact = C Active Region = E 5.2 - iC v BC iB βR = C + B + V + - E vBE For VBE > 0 and VBC = 0, IC = β F I B or β F = iE - IC 275μA = = 68.8 4μA IB 0.5 αR = =1 1− α R 1− 0.5 ⎛V ⎞ IC = I S exp⎜ BE ⎟ or I S = ⎝ VT ⎠ IC 275μA = = 2.10 fA ⎛ VBE ⎞ ⎛ 0.64 ⎞ exp⎜ ⎟ exp⎜ ⎟ ⎝ 0.025 ⎠ ⎝ VT ⎠ 5.3 i vBE i B - E E + B V + - + v BC C - iC For VBC > 0 and VBE = 0, I E = −β R I B or β R = − βF = ⎛ −275μA ⎞ IE = −⎜ ⎟ = 2.20 IB ⎝ 125μA ⎠ αF 0.975 = = 39 1− α F 1− 0.975 ⎛V ⎞ I E = −I S exp⎜ BC ⎟ or I S = ⎝ VT ⎠ IC 275μA = = 3.13 fA ⎛ VBE ⎞ ⎛ 0.63 ⎞ exp⎜ ⎟ exp⎜ ⎟ ⎝ 0.025 ⎠ ⎝ VT ⎠ 123 5.4 Using β = α β and α = : 1− α β +1 Table 5.P1 0.167 0.200 0.400 0.667 0.750 3.00 0.909 10.0 0.980 49.0 0.995 200 0.999 1000 0.9998 5000 5.5 (a) For this circuit, VBE = 0 V, VBC = -5 V and I = IC. Substituting these values into the collector current expression in Eq. (5.13): ⎡ ⎛ −5 ⎞⎤ I S ⎡ ⎛ −5 ⎞ ⎤ IC = I S ⎢exp(0)− exp⎜ ⎟⎥ − ⎢exp⎜ ⎟ −1⎥ ⎝ .025 ⎠⎦ β R ⎣ ⎝ .025 ⎠ ⎦ ⎣ ⎛ ⎛ 1⎞ 1⎞ I = IC = I S ⎜1+ ⎟ = 10−15 A⎜1+ ⎟ = 2 fA. ⎝ 1⎠ ⎝ βR ⎠ (b) For this circuit, the constraints are VBC = -5 V and IE = 0. Substituting these values into the emitter current expression in Eq. (5.13): ⎡ ⎛V ⎞ ⎛ V ⎞⎤ I ⎡ ⎛ V ⎞ ⎤ I E = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ + S ⎢exp⎜ BE ⎟ −1⎥ = 0 which gives ⎝ VT ⎠⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎛V ⎞ ⎛V ⎞ βF 1 + exp⎜ BC ⎟. Substituting this result into IC : exp⎜ BE ⎟ = ⎝ VT ⎠ 1+ β F 1+ β F ⎝ VT ⎠ ⎛ V ⎞⎤ I ⎡ ⎛ V ⎞ ⎤ I ⎡ ICBO = S ⎢1− exp⎜ BC ⎟⎥ − S ⎢exp⎜ BC ⎟ −1⎥. 1+ β F ⎣ ⎝ VT ⎠⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎡ 1 ⎡ 1 1⎤ 1⎤ + ⎥ = 10−15 A⎢ + ⎥ = 1.01 fA, and For VBC = -5V , ICBO = I S ⎢ ⎣101 1⎦ ⎣1+ β F β R ⎦ ⎛ 1 ⎞ ⎛ 1 ⎞ VBE = VT ln⎜ ⎟ = 0.025V ln⎜ ⎟ = −0.115 V ≠ 0! ⎝101⎠ ⎝1+ β F ⎠ 5.6 124 IB + 150 μA B VBC - C IC (a) - (c) (b) npn transistor E + V BE IE (d) VBE = VBC I S ⎡ ⎛ VBE ⎞ ⎤ ⎢exp⎜ ⎟ −1⎥ β R ⎣ ⎝ VT ⎠ ⎦ I ⎡ ⎛V ⎞ ⎤ I E = + S ⎢exp⎜ BE ⎟ −1⎥ β F ⎣ ⎝ VT ⎠ ⎦ ⎛ 1 1 ⎞ ⎡ ⎛V ⎞ ⎤ IB = IS ⎜ + ⎟ ⎢exp⎜ BE ⎟ −1⎥ ⎝ β F β R ⎠ ⎣ ⎝ VT ⎠ ⎦ (e) I IE = IB C =− 1 1+ and βF βR IE β =− R IC βF βF I = − 400I E and I B = I E − IC = 401 I E βR E For the circuit I B = 150μA 150μA Therefore I E = = 0.374 μA, and IC = −149.6 μA. (f ) Using VBC = VBE IC = − 401 ⎛ ⎞ ⎛ ⎞ ⎜ ⎟ ⎜ ⎟ IB 150μA ⎜ ⎟ ⎜ ⎟ = 0.591 V = (0.025V )ln = VT ln ⎞ ⎛ ⎞ ⎜ ⎛ 1 ⎟ ⎜ 1 1 ⎟ 1 + + ⎟⎟ ⎟⎟ ⎜ IS ⎜ ⎜ 2 fA⎜ ⎝ 100 0.25 ⎠ ⎠ ⎝ ⎝ ⎝ βF βR ⎠ ⎠ 5.7 VBC IB - C IC + B npn transistor + V BE E - IE ⎛ 1 ⎞⎡ ⎛ VBE ⎞ ⎤ IE | IC = β F I B For VBC = 0, I E = I S ⎜1+ ⎟⎢exp⎜ ⎟ −1⎥ | I B = βF + 1 ⎝ β F ⎠⎣ ⎝ VT ⎠ ⎦ 175μA 100 = 1.73 μA | IC = 175μA = 173 μA 101 101 ⎛ β ⎛100 175μA ⎞ IE ⎞ = VT ln⎜ F + 1⎟ = 0.025V ln⎜ + 1⎟ = 0.630 V ⎠ ⎝ 101 2 fA ⎠ ⎝ βF + 1 IS I E = 175 μA | I B = 175 μA VBE 125 5.8 - E IE VBE IB npn transistor + B + V BC C - IC 175 μA ⎛ 1 ⎞⎡ ⎛ V ⎞ ⎤ I For VBE = 0, IC = −I S ⎜1+ ⎟⎢exp⎜ BC ⎟ −1⎥ | I B = − C | I E = −β R I B βR + 1 ⎝ β R ⎠⎣ ⎝ VT ⎠ ⎦ ⎛ −175μA ⎞ 0.25 IC = −175 μA | I B = −⎜ 175μA = −35 μA ⎟ = 140 μA | I E = − 1.25 ⎝ 1.25 ⎠ ⎛ β ⎞ ⎛ 0.25 175μA ⎞ I + 1⎟ = 0.590 V VBC = VT ln⎜− R C + 1⎟ = 0.025V ln⎜ ⎝ 1.25 2 fA ⎠ ⎝ βR + 1 IS ⎠ 5.9 Using vBC = 0 in Eq. 5.13 and recognizing that i = iC + iB = iE : ⎛ 1 ⎞⎡ ⎛ vBE ⎞ ⎤ i = iE = I S ⎜1 + ⎟⎢exp⎜ ⎟ − 1⎥ , and the reverse saturation current ⎝ β F ⎠⎣ ⎝ VT ⎠ ⎦ ⎛ ⎛ 1 ⎞ 1 ⎞ of the diode connected transistor is I S' = I S ⎜1 + ⎟ = (2 fA)⎜1 + ⎟ = 2.02 fA ⎝ 100 ⎠ ⎝ βF ⎠ 5.10 Using vBE = 0 in Eq. 5.13 and recognizing that i = −iC : ⎛ 1 ⎞⎡ ⎛ v ⎞ ⎤ i = −iC = −I S ⎜1 + ⎟⎢exp⎜ BC ⎟ − 1⎥ , and the reverse saturation current ⎝ β R ⎠⎣ ⎝ VT ⎠ ⎦ ⎛ ⎛ 1⎞ 1⎞ of the diode connected transistor is I S' = I S ⎜1 + ⎟ = (5 fA)⎜1 + ⎟ = 6.67 fA ⎝ 3⎠ ⎝ βR ⎠ 5.11 ⎡ ⎛v ⎞ ⎡ ⎛ 0.75 ⎞ ⎛ v ⎞⎤ ⎛ −3 ⎞⎤ = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ = 5x10−16 A⎢exp⎜ ⎟ − exp⎜ ⎟⎥ = 5.34 mA ⎝ 0.025 ⎠⎦ ⎝ VT ⎠⎦ ⎣ ⎝ 0.025 ⎠ ⎣ ⎝ VT ⎠ (b) The current is symmetric: For VBC = 0.75 V and VBE = -3 V, iT = -5.34 mA. (a) i T 5.12 ⎡ ⎛v ⎞ ⎡ ⎛ 0.70 ⎞ ⎛ vBC ⎞⎤ ⎛ −3 ⎞⎤ −15 BE a i = I exp A exp = 10 − exp − exp ⎢ ⎥ ⎢ ⎜ ⎟ ⎜ ⎟⎥ = 1.45 mA ( ) T S ⎜⎝ V ⎟⎠ ⎜⎝ V ⎟⎠ ⎝ 0.025 ⎠⎦ ⎣ ⎝ 0.025 ⎠ ⎣ T T ⎦ (b) The current is symmetric: For VBC = 0.70 V and VBE = -3 V, iT = -1.45 mA. 5.13 Base Contact = F p-type Emitter = D 5.14 126 Collector Contact = G p-type Collector = A Emitter Contact = E Active Region = C (a) pnp transistor v iB EB E E - B v 100 μA i + C CB + iC (b)-(c) (d) Using Eq. (5.17) with vEB = 0 and dropping the "-1" terms: ⎛ ⎛v ⎞ ⎛v ⎞ 1 ⎞ ⎛v ⎞ I iC = −I S ⎜1+ ⎟ exp⎜ CB ⎟ iE = −I S exp⎜ CB ⎟ iB = S exp⎜ CB ⎟ βR ⎝ β R ⎠ ⎝ VT ⎠ ⎝ VT ⎠ ⎝ VT ⎠ IE βR 1 IE = = = αR = −β R 1 IC βR + 1 IB 1+ βR IC = −100μA, I E = α R IC = 0.25IC = −25.0μA αR I 0.25 1 IB = − E β R = = = I B = +75μA βR 1− α R 1− 0.25 3 α 0.985 βF = F = = 65.7 1− α F 1− 0.985 ⎛V ⎞ ⎛ I ⎞ VEB = 0 and I E = −I S exp⎜ CB ⎟ VCB = VT ln⎜ − E ⎟ ⎝ VT ⎠ ⎝ Is ⎠ ⎛ −25x10−6 A ⎞ VCB = 0.025V ln⎜ − ⎟ = 0.599 V 10−15 A ⎠ ⎝ 127 5.15 (a) pnp VCB IC + C - IB B V + V EB E + IE (b)-(c) (d) Using Eq. (5.17) with vCB = 0 and droping the "-1" terms: ⎛ ⎛v ⎞ 1 ⎞ ⎛ vEB ⎞ iE = I S ⎜1 + iC = −I S exp⎜ EB ⎟ ⎟ exp⎜ ⎟ ⎝ β F ⎠ ⎝ VT ⎠ ⎝ VT ⎠ IC 300μA = = 2.29 fA IS = ⎛ VEB ⎞ ⎛ 0.640 ⎞ exp⎜ ⎟ exp⎜ ⎟ ⎝ 0.025V ⎠ ⎝ VT ⎠ βF = iB = ⎛v ⎞ exp⎜ EB ⎟ βF ⎝ VT ⎠ IS αR IC 300μA 0.2 = = 75 | β R = = = 0.25 4μA IB 1− α R 1− 0.2 5.16 Using VCB = 0 in Eq. 5.17 and recognizing that i = iE : ⎛ 1 ⎞⎡ ⎛ vEB ⎞ ⎤ i = iE = I S ⎜1 + ⎟⎢exp⎜ ⎟ − 1⎥ , and the reverse saturation current ⎝ β F ⎠⎣ ⎝ VT ⎠ ⎦ ⎛ ⎛ 1 ⎞ 1 ⎞ of the diode connected transistor is I S' = I S ⎜1 + ⎟ = (2 fA)⎜1 + ⎟ = 2.02 fA ⎝ 100 ⎠ ⎝ βF ⎠ 5.17 v CB + 35 μA i C C B i B - v E EB + iE (a)-(c) (b) pnp transistor(d) ⎛ 1 I ⎡ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ 1 ⎞⎡ ⎛ v ⎞ ⎤ + ⎟⎢exp⎜ EB ⎟ −1⎥ vEB = vCB iC = − S ⎢exp⎜ EB ⎟ −1⎥ iE = + S ⎢exp⎜ EB ⎟ −1⎥ iB = + I S ⎜ β R ⎣ ⎝ VT ⎠ ⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎝ β F β R ⎠⎣ ⎝ VT ⎠ ⎦ 1 IE βR 4 IE β 4 βF = = = = 0.0506 = − R = − = −0.0533 1 1 IB β F + β R 79 IB βF 75 + βF 128 βR 4 75 I B = 1.77 μA IC = − I E = −33.2 μA 79 4 ⎛ 4 −33.2x10−6 A ⎛ β R IC ⎞ VCB = VEB = 0.025V ln⎜1− = VT ln⎜1− ⎟ ⎜ Is ⎠ 2x10−15 A ⎝ ⎝ I B = 35 μA VEB IE = ( )⎟⎞ = 0.623 V ⎟ ⎠ 5.18 C IC VCB + IB B V EB E + IE pnp transistor ⎛ 1 ⎞ ⎡ ⎛ VEB ⎞ ⎤ For VCB = 0, I E = I S ⎜1+ ⎟ ⎢exp⎜ ⎟ −1⎥ ⎝ β F ⎠ ⎣ ⎝ VT ⎠ ⎦ | IB = IE | IC = β F I B βF + 1 300μA = 2.97 μA | IC = 100(2.97μA)= 297 μA 101 ⎤ ⎡⎛ β ⎞ I ⎡⎛ 100 ⎞ 300μA ⎤ = VT ln⎢⎜ F ⎟ E + 1⎥ = 0.025V ln⎢⎜ + 1⎥( )= 0.626 V ⎟ ⎦ ⎣⎝ 101⎠ 4 fA ⎣⎝ β F + 1⎠ I S ⎦ I E = 300 μA | I B = I VEB 5.19 VEB IB + E IE B V CB I C + IC pnp transistor ⎛ 1 ⎞⎡ ⎛ V ⎞ ⎤ I | I E = −β R I B For VEC = 0, IC = −I S ⎜1+ ⎟⎢exp⎜ CB ⎟ −1⎥ | I B = − C βR + 1 ⎝ β R ⎠⎣ ⎝ VT ⎠ ⎦ ⎛ −300μA ⎞ IC = −300 μA | I B = −⎜ ⎟ = 150 μA | I E = −1(150μA)= −150 μA ⎝ 2 ⎠ ⎡ ⎛ β ⎞I ⎤ ⎡ 1 ⎛ −300μA ⎞ ⎤ VCB = VT ln⎢−⎜ R ⎟ C + 1⎥ = 0.025V ln⎢− ⎜ ⎟ + 1⎥ = 0.603 V ⎣ 2 ⎝ 5 fA ⎠ ⎦ ⎣ ⎝ β R + 1⎠ I S ⎦ 5.20 ⎡ ⎛v ⎞ ⎡ ⎛ 0.70 ⎞ ⎛ v ⎞⎤ ⎛ −3 ⎞⎤ = I S ⎢exp⎜ EB ⎟ − exp⎜ CB ⎟⎥ = 5x10−16 A⎢exp⎜ ⎟ − exp⎜ ⎟⎥ = 723 μA ⎝ 0.025 ⎠⎦ ⎝ VT ⎠⎦ ⎣ ⎝ 0.025 ⎠ ⎣ ⎝ VT ⎠ (b) The current is symmetric: For VCB = 0.75 V and VEB = -3 V, iT = -723 μA. (a) i T 129 5.21 ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ 0.73V ⎞ ⎤ i = I a ⎢ ( ) F S exp⎜⎝ VBE ⎟⎠ −1⎥ = 4x10−15 A⎢exp⎜⎝ 0.025V ⎟⎠ −1⎥ = 19.2 mA ⎣ ⎦ ⎣ ⎦ T ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ −3V ⎞ ⎤ iR = I S ⎢exp⎜ BC ⎟ −1⎥ = 4x10−15 A⎢exp⎜ ⎟ −1⎥ = −4.00 fA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ 19.2mA i −4.00 fA = 240 μA | R = = −2.00 μA βF βR 80 2 ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ −3V ⎞ ⎤ (b) iF = I S ⎢exp⎜⎝ VBE ⎟⎠ −1⎥ = 4x10−15 A⎢⎣exp⎜⎝ 0.025V ⎟⎠ −1⎥⎦ = −4.00 fA ⎦ ⎣ T ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ 0.73V ⎞ ⎤ iR = I S ⎢exp⎜ BC ⎟ −1⎥ = 4x10−15 A⎢exp⎜ ⎟ −1⎥ = 19.2 mA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ iT = iF − iR = 19.2 mA | iF iT = iF − iR = −19,2 mA | = iF βF −4.00 fA i 19.2mA = −0.05 μA | R = = 9.60 mA βR 80 2 = 5.22 ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ 0.68V ⎞ ⎤ = I S ⎢exp⎜ EB ⎟ −1⎥ = 6x10−15 A⎢exp⎜ ⎟ −1⎥ = 3.90 mA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ −3V ⎞ ⎤ iR = I S ⎢exp⎜ CB ⎟ −1⎥ = 6x10−15 A⎢exp⎜ ⎟ −1⎥ = −6.00 fA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ (a) i F 3.90mA i −6.00 fA = 65.0 μA | R = = −2.00 μA βF βR 60 3 ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ −3V ⎞ ⎤ (b) iF = I S ⎢exp⎜⎝ VEB ⎟⎠ −1⎥ = 6x10−15 A⎢⎣exp⎜⎝ 0.025V ⎟⎠ −1⎥⎦ = −6.00 fA ⎣ ⎦ T ⎡ ⎛v ⎞ ⎤ ⎡ ⎛ 0.68V ⎞ ⎤ iR = I S ⎢exp⎜ CB ⎟ −1⎥ = 6x10−15 A⎢exp⎜ ⎟ −1⎥ = 3.90 mA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ iT = iF − iR = 3.90 mA | iT = iF − iR = −3.90 mA | 130 iF iF = βF = −6.00 fA i 3.90mA = −0.100 fA | R = = 1.30 mA 60 3 βR 5.23 ⎡ ⎛v ⎞ ⎡ ⎛v ⎞ ⎛ v ⎞⎤ I ⎡ ⎛ v ⎞ ⎤ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ iE = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ + S ⎢exp⎜ BE ⎟ −1⎥ = I S ⎢exp⎜ BE ⎟ −1− exp⎜ BC ⎟ + 1⎥ + S ⎢exp⎜ BE ⎟ −1⎥ ⎝ VT ⎠⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎝ VT ⎠ ⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎣ ⎝ VT ⎠ ⎡ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ ⎛ ⎛ v BC ⎞ ⎤ 1 ⎞⎡ ⎛ vBE ⎞ BC S BE BC iE = I S ⎜1+ exp exp exp −1− exp + 1 − I −1 = −1 − I ⎢ ⎥ ⎢ ⎥ ⎢ ⎥ ⎟ ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎟ −1⎥ S S ⎢exp⎜ ⎝ β F ⎠⎣ ⎝ VT ⎠ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ α F ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎡ ⎛v ⎞ ⎛ v ⎞⎤ I ⎡ ⎛ v ⎞ ⎤ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ iC = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ − S ⎢exp⎜ BC ⎟ −1⎥ = I S ⎢exp⎜ BE ⎟ −1− exp⎜ BC ⎟ + 1⎥ − S ⎢exp⎜ BC ⎟ −1⎥ ⎝ VT ⎠⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎝ VT ⎠ ⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎣ ⎝ VT ⎠ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ ⎛ 1 ⎞⎡ ⎛ v ⎞ ⎤ iC = I S ⎢exp⎜ BE ⎟ −1⎥ − I S ⎜1+ ⎟⎢exp⎜ BC ⎟ −1⎥ = I S ⎢exp⎜ BE ⎟ −1⎥ − S ⎢exp⎜ BC ⎟ −1⎥ ⎝ β R ⎠⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ α R ⎣ ⎝ VT ⎠ ⎦ Defining I ES = IS αF and ICS = IS αR , then we see I S = α F I ES = α R ICS and ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iE = I ES ⎢exp⎜ BE ⎟ −1⎥ − α R I S ⎢exp⎜ BC ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iC = α F I ES ⎢exp⎜ BE ⎟ −1⎥ − ICS ⎢exp⎜ BC ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iB = iE − iC = (1− α F )I ES ⎢exp⎜ BE ⎟ −1⎥ + (1− α R )I S ⎢exp⎜ BC ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ 5.24 αF = βF βR 100 0.5 I 2 fA = 0.990 | α R = = = 0.333 | I ES = S = = 2.02 fA β F + 1 101 β R + 1 1.5 α F 0.990 ICS = IS αR = = 2 fA = 6.00 fA | α F I ES = α R ICS = I S 0.333 131 5.25 ⎡ ⎛v ⎞ ⎡ ⎛v ⎞ ⎤ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ ⎛ 1 ⎞⎡ ⎛ v EB ⎞ ⎤ CB iE = I S ⎢exp⎜ EB ⎟ −1− exp⎜ CB ⎟ + 1⎥ + S ⎢exp⎜ EB ⎟ −1⎥ = I S ⎜1+ ⎟⎢exp⎜ ⎟ −1⎥ − I S ⎢exp⎜ ⎟ −1⎥ ⎝ VT ⎠ ⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎝ β F ⎠⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎡ ⎛v ⎞ ⎤ ⎛v ⎞ ⎤ I ⎡ ⎛v ⎞ ⎤ ⎛ 1 ⎞⎡ ⎛ v ⎞ ⎤ iC = I S ⎢exp⎜ EB ⎟ −1− exp⎜ CB ⎟ + 1⎥ − S ⎢exp⎜ CB ⎟ −1⎥ = I S ⎢exp⎜ EB ⎟ −1⎥ − I S ⎜1+ ⎟⎢exp⎜ CB ⎟ −1⎥ ⎝ VT ⎠ ⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎝ β R ⎠⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iE = I ES ⎢exp⎜ EB ⎟ −1⎥ − α R ICS ⎢exp⎜ CB ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iC = α F I ES ⎢exp⎜ EB ⎟ −1⎥ − ICS ⎢exp⎜ CB ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛v ⎞ ⎤ ⎡ ⎛v ⎞ ⎤ iB = iE − iC = (1− α F )I ES ⎢exp⎜ EB ⎟ −1⎥ + (1− α R )ICS ⎢exp⎜ CB ⎟ −1⎥ ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ 5.26 At IC = 5 mA and VCE = 5 V , I B = 60μA : β F = IC 5mA = = 83.3 I B 60μA At IC = 7 mA and VCE = 7.5 V , I B = 80μA : β F = IC 7mA = = 87.5 I B 80μA At IC = 10 mA and VCE = 14 V , I B = 100μA : β F = IC 10mA = = 100 I B 100μA 5.27 See Problem 5.28 5.28 20mA 10mA 0A -4mA 0V 2V 4V 6V -I(VCC) V_VCC 132 8V 10V 5.29 3.0mA 2.0mA 1.0mA 0A -1.0mA -2V 0V 2V 4V 6V 8V 10V -I(VCB) V_VCB 5.30 See Problem 5.31 5.31 20mA 10mA 0A -4mA 0V 2V 4V 6V 8V 10V -I(VEC) V_VEC 133 5.32 3.0mA 2.0mA 0A -1.0mA -2V 0V 2V 4V 6V 8V 10V -I(VBC) V_VBC 5.33 The change in vBE for a decade change in iC is ΔVBE = VT ln (10) = 2.30VT . ⎛1.38x10-23 ⎞ kT The reciprocal of the slope is 2.30VT = 2.30 = 2.30⎜ ⎟T (V/dec) -19 q ⎝1.60x10 ⎠ (a) 39.6 mV/dec (b) 49.5 mV/dec (c) 59.4 mV/dec (d) 69.3 mV/dec 5.34 (a) The break down voltage is equal to that of the emitter-base junction: VZ = 6 V. (b) The break down voltage is determined by the base-collector junction: VZ = 50 V. (c) The break down voltage is set by the emitter-base junction: VZ = 6 V. 5.35 (a) The base-emitter junction breaks down with VEB = 6.3 V. 5 − 6.3 − (−5) V = 2.31 mA IR = Ω 1600 (b) The base-emitter junction is forward biased; VBE = 0.7 V 5 − 0.7 − (−5) V IR = = 388 μA 24000 Ω (c) VBE = 0, and the collector-base junction is reversed biased with VBC ≈ -10V which is less than the breakdown voltage of 75 V. The transistor is operating in cutoff. ⎛ I 1⎞ Using Eq. (5.13), I R = IC = I S (1− 0)− S (0 −1)= I S ⎜1+ ⎟ ≈ 0 βR ⎝ βR ⎠ 5.36 VCE = VCB + VBE = VCB + 0.7 ≤ 65.7 V 134 5.37 (a) IB is forced to be negative by the current source, and the largest negative base current according to the Transport model is ⎛ 1 ⎛1 1⎞ 1 ⎞ IB = −IS ⎜ + ⎟ = −10−15 A⎜ + ⎟ = −2.02 fA ⎝ 50 0.5 ⎠ ⎝ βF βR ⎠ . (b) IB is forced to be -1 mA by the current source. One or both of the junctions must enter the breakdown region in order to supply this current. For the case of a normal BJT, the base-emitter junction will break down and supply the current since it has the lower reverse breakdown voltage. 5.38 Base-Emitter Voltage Base-Collector Voltage 0.7 V -5.0 V -5.0 V Reverse Active Cutoff 0.7 V Saturation Forward Active 5.39 (a) vBE > 0, vBC = 0, forward-active region; vBE = 0, vBC > 0, reverse-active region; vBE > 0, vBC = 0, forward-active region (b) vEB < 0, vCB < 0, cutoff region (c) vEB > 0, vCB < 0, forward-active region (d) vBE > 0, vBC < 0, forward-active region; vBE > 0, vBC > 0, saturation region 5.40 (a) vBE = 0, vBC < 0 cutoff region (b) vBC < 0, IE = 0, cutoff region 5.41 (a) vBE > 0, vBC > 0 saturation region (b) vBE > 0, vBC = 0, forward-active region (c) vBE = 0, vBC > 0, reverse-active region 135 5.42 Emitter-Base Voltage Collector-Base Voltage 0.7 V -0.65 V 0.7 V Saturation Forward Active -0.65 V Reverse Active Cutoff 5.43 (a) vBE > 0, vBC = 0, forward-active region (b) vBE = 0, vBC > 0, reverse-active region 5.44 (a) vEB = 0, vCB > 0, reverse-active region (b) vEB > 0, vCB = 0, forward-active region 5.45 (a) vEB > 0, vCB > 0, saturation region (b) vEB > 0, vCB = 0, forward-active region (c) vEB = 0, vCB > 0, reverse-active region 5.46 (a ) pnp transistor with VEB = −3V and VCB = −3V → Cutoff | Using Eq. (5.17) : 10−15 A I 10−15 A = 0.5x10-15 = 0.5 fA | I E = − S = = 13.3x10-18 = 13.3 aA 2 75 βR βF ⎛ 1 ⎛ 1 1⎞ 1⎞ + ⎟ = 10−15 A⎜ + ⎟ = 0.263x10−15 = 0.263 fA I B = −I S ⎜ ⎝ 75 4 ⎠ ⎝ βF βR ⎠ IC = + IS = (b) npn transistor with V BE = −5V and VBC = −5V → Cutoff | The currents are the same as in part (a). 5.47 ⎡ ⎛ 0.3 ⎞ ⎛ −5 ⎞⎤ 10−16 ⎡ ⎛ −5 ⎞ ⎤ iC = 10−16 ⎢exp⎜ − exp ⎢exp⎜ ⎟ ⎜ ⎟⎥ − ⎟ −1⎥ = 16.3 pA 1 ⎣ ⎝ 0.025⎠ ⎦ ⎝ 0.025 ⎠⎦ ⎣ ⎝ 0.025 ⎠ ⎡ ⎛ 0.3 ⎞ ⎛ −5 ⎞⎤ 10−16 ⎡ ⎛ 0.3 ⎞ ⎤ iE = 10−16 ⎢exp⎜ ⎢exp⎜ ⎟ − exp⎜ ⎟⎥ + ⎟ −1⎥ = 17.1 pA ⎝ 0.025 ⎠⎦ 19 ⎣ ⎝ 0.025⎠ ⎦ ⎣ ⎝ 0.025 ⎠ 10−16 ⎡ ⎛ 0.3 ⎞ ⎤ 10−16 ⎡ ⎛ −5 ⎞ ⎤ iB = ⎢exp⎜ ⎢exp⎜ ⎟ −1⎥ + ⎟ −1⎥ = 0.857 pA 19 ⎣ ⎝ 0.025 ⎠ ⎦ 1 ⎣ ⎝ 0.025 ⎠ ⎦ 136 These currents are all very small - for most practical purposes it still appears to be cutoff. Since VBE > 0 and VBC < 0, the transistor is actually operating in the forward-active region. Note that I C = β FI B . 5.48 An npn transistor with VBE = 0.7V and VBC = −0.7V → Forward - active region Using Eq. (5.45) : I E = (β F + 1)I B | β F = IE 10mA −1 = −1 = 65.7 0.15mA IB ⎛ 1 ⎞ ⎛V ⎞ 0.01A = 6.81x10−15 A = 6.81 fA I E = I S ⎜1+ ⎟ exp⎜ BE ⎟ | I S = ⎛ ⎞ ⎛ ⎞ 1 0.7 ⎝ β F ⎠ ⎝ VT ⎠ ⎜1+ ⎟ exp⎜ ⎟ ⎝ 65.7 ⎠ ⎝ 0.025⎠ 5.49 A pnp transistor with VEB = 0.7V and VCB = −0.7V ⇒ Forward - active region ⎛V ⎞ I 2.5mA 2.5mA Using Eq. (5.44) : β F = C = = 62.5 | IC = I S exp⎜ EB ⎟ | I S = = 1.73 fA ⎛ 0.7V ⎞ I B 0.04mA ⎝ VT ⎠ exp⎜ ⎟ ⎝ 0.025V ⎠ 5.50 IE = −0.7V − (−3.3V ) 47kΩ = 55.3μA | I B = IE 55.3μA = = 0.683μA 81 βF + 1 IC = β F I B = 80(0.683μA)= 54.6μA | Check : I B + IC = I E is ok 5.51 (a) f β = fT βF = 500 MHz = 6.67 MHz 759 (b) The graph represents the Bode magnitude plot. Thus β (s) = βF 1+ s ωβ = βFωβ ωT = s + ωβ s + ωβ ωT βF β (s) s + ωβ βFωβ ωT αF βF + 1 α (s)= = = = = ≈ ωT s s s + ωT + ω β s + (β F + 1)ω β β (s)+ 1 +1 1+ 1+ s + ωβ ωT (β F + 1)ω β α ( jω ) = αF ⎛ ω ⎞2 1+ ⎜ ⎟ ⎝ ωT ⎠ 137 5.52 vEB > 0 vCB < −4VT ⎛V ⎞ I ⎛V ⎞ iC = I S exp⎜ EB ⎟ + S ≈ I S exp⎜ EB ⎟ ⎝ VT ⎠ β R ⎝ VT ⎠ ⎛V ⎞ I ⎛V ⎞ I ⎛V ⎞ iE = I S exp⎜ EB ⎟ + S exp⎜ EB ⎟ = S exp⎜ EB ⎟ ⎝ VT ⎠ β F ⎝ VT ⎠ α F ⎝ VT ⎠ ⎛V ⎞ I ⎛V ⎞ I I iB = S exp⎜ EB ⎟ − S ≈ S exp⎜ EB ⎟ βF ⎝ VT ⎠ β R β F ⎝ VT ⎠ iC = β F iB | iC = α F iE iB iC C B - + i = β i vEB C F B 0.7 V i E E 5.53 An npn transistor with VBE = −0.7V and VBC = +0.7V → Reverse - active region Using Eq. (5.51) : IC = −(β R + 1)I B | β R = − ⎛V ⎞ I E = −I S exp⎜ BC ⎟ | I E = −35μA | I S = − ⎝ VT ⎠ IC −75μA −1 = − −1 = 0.875 40μA IB −35μA = 2.42x10−17 A = 0.0242 fA = 24.2 aA ⎛ 0.7 ⎞ exp⎜ ⎟ ⎝ 0.025⎠ 5.54 A pnp transistor with VEB = −0.7 V and VCB = +0.7 V → Reverse − active region ⎛V ⎞ I ⎛V ⎞ ⎛V ⎞ I iC = −I S exp⎜ CB ⎟ − S exp⎜ CB ⎟ = − S exp⎜ CB ⎟ αR ⎝ VT ⎠ β R ⎝ VT ⎠ ⎝ VT ⎠ ⎛V ⎞ I ⎛V ⎞ iE = −I S exp⎜ CB ⎟ − S ≅ −I S exp⎜ CB ⎟ ⎝ VT ⎠ β F ⎝ VT ⎠ ⎛V ⎞ I ⎛V ⎞ I I iB = − S + S exp⎜ CB ⎟ ≅ S exp⎜ CB ⎟ βF βR ⎝ VT ⎠ β R ⎝ VT ⎠ βR = − 5.55 IC = − (−0.1mA) = 0.667 | I = − iE =− S iB 0.15mA −0.7V − (−3.3V ) 56kΩ iE −10−4 A =− = 6.91x10−17 A ⎛ VCB ⎞ ⎛ 0.7 ⎞ exp⎜ exp⎜ ⎟ ⎟ ⎝ 0.025⎠ ⎝ VT ⎠ = −46.4 μA | I B = − IC −46.4μA =− = 26.5 μA 1.75 βR + 1 I E = IC + I B = −46.4μA + 26.5μA = −19.9 μA 138 5.56 ⎡ ⎤ β 1+ FOR ⎥ ⎢ ⎛ 1 ⎞ (β R + 1)⎥ βR I 1mA 2 | αR = β FOR = C = = 1 | VCESAT = VT ln⎢⎜ ⎟ = ⎢⎝ α R ⎠ ⎛β ⎞ ⎥ I B 1mA βR + 1 3 1− ⎜ FOR ⎟ ⎥ ⎢ ⎝ βF ⎠ ⎦ ⎣ ⎡ 1 ⎤ ⎢ 1+ ⎥ ⎛ 3 ⎞ (2 + 1)⎥ ⎢ = 17.8 mV VCESAT = 0.025ln ⎜ ⎟ ⎢⎝ 2 ⎠ ⎛1⎞⎥ 1− ⎜ ⎟ ⎥ ⎢ ⎝ 50 ⎠ ⎦ ⎣ ⎡ ⎤ ⎢ ⎥ ⎡ 1mA + (1− 0.667)1mA ⎤ I B + (1− α R )IC ⎥ ⎢ ⎥ = 0.724 V = 0.025V )ln⎢ −15 VBE = VT ln ⎞⎥ ( ⎢ ⎛ 1 ⎢⎣10 A(0.02 + 1− .0.667)⎥⎦ + 1− α R ⎟ ⎥ ⎢ IS ⎜ ⎠⎦ ⎣ ⎝ βF 5.57 ⎛v ⎞ I ⎛v ⎞ ⎛v ⎞ I ⎛v ⎞ I iC = I S exp⎜ EB ⎟ − S exp⎜ CB ⎟ | iB = S exp⎜ EB ⎟ + S exp⎜ CB ⎟ | Simultaneous βF ⎝ VT ⎠ α R ⎝ VT ⎠ ⎝ VT ⎠ β R ⎝ VT ⎠ i iB − C iB + (1− α R )iC βF solution yields : vEB = VT ln | vCB = VT ln ⎤ ⎤ ⎡1 ⎡ 1 ⎤⎡ 1 I S ⎢ + (1− α R )⎥ I S ⎢ ⎥⎢ + (1− α R )⎥ ⎦ ⎦ ⎣β F ⎣α R ⎦⎣β F ⎡ ⎤ iC 1+ ⎢ ⎥ ⎛ 1 ⎞ (β R + 1) iB ⎥ i ⎢ vECSAT = vEB − vCB = VT ln ⎜ ⎟ for i B > C ⎢⎝ α R ⎠ ⎥ i βF 1− C ⎢ ⎥ β F iB ⎦ ⎣ 5.58 (a) Substituting iC = 0 in Eq. 5.30 gives ⎛ 1 ⎞ ⎛ 1 ⎞ VCESAT = VT ln⎜ ⎟ = (0.025V )ln⎜ ⎟ = 0.0173 V = 17.3 mV ⎝ 0.5⎠ ⎝αR ⎠ (b) By symmetry ⎛ 1 ⎞ VECSAT = VT ln⎜ ⎟ ⎝αF ⎠ or by using iE = 0 and iC = -iB, 139 VCESAT βR 1 1− ⎛ 1 ⎞ β +1 ⎛ 1 ⎞ β +1 ⎛ 1 ⎞α R = VT ln⎜ ⎟ = VT ln⎜ ⎟ R = VT ln⎜ ⎟ R ⎝ α R ⎠ 1+ 1 ⎝ α R ⎠ βF + 1 ⎝αR ⎠ 1 βF βF αF ⎛ 1 ⎞ VCESAT = VT ln (α F ) and VECSAT = VT ln⎜ ⎟ ⎝αF ⎠ ⎛ 1 ⎞ ⎛ 1 ⎞ VECSAT = VT ln⎜ ⎟ = (0.025V )ln⎜ ⎟ = 0.000251 V = 0.251 mV ⎝ 0.99 ⎠ ⎝αF ⎠ 5.59 (a) Substituting iC = 0 in Eq. 5.30 gives ⎛ 1 ⎞ ⎛ 1 ⎞ VCESAT = VT ln⎜ ⎟ = (0.025V )ln⎜ ⎟ = 27.7 mV ⎝ 0.33⎠ ⎝αR ⎠ (b) By symmetry ⎛ 1 ⎞ ⎛ 1 ⎞ VECSAT = VT ln⎜ ⎟ = (0.025V )ln⎜ ⎟ = 1.28 mV ⎝ 0.95⎠ ⎝αF ⎠ 5.60 (a) VCESAT ⎡ ⎤ β 1+ FOR ⎥ ⎢ ⎛ 1 ⎞ (β R + 1)⎥ 0.9 βR = VT ln⎢⎜ ⎟ = = 0.4737 | αR = ⎢⎝ α R ⎠ ⎛ β FOR ⎞ ⎥ β R + 1 0.9 + 1 1− ⎜ ⎢ ⎟⎥ ⎝ βF ⎠ ⎦ ⎣ ⎡ β FOR ⎤ 1+ ⎢ ⎥ ⎛ 1 ⎞ (0.9 + 1)⎥ ⎢ 0.1 = 0.025ln ⎜ → β FOR = 11.05 ⎢⎝ 0.4737 ⎟⎠ ⎛ β FOR ⎞ ⎥ 1− ⎜ ⎢ ⎟⎥ ⎝ 15 ⎠ ⎦ ⎣ 1+ 0.4737exp(4) = β FOR (0.9 + 1) → β ⎛β ⎞ 1− ⎜ FOR ⎟ ⎝ 15 ⎠ FOR = 11.05 | I B = IC β FOR = 20 A = 1.81A 11.05 ⎡ β FOR ⎤ 1+ ⎢⎛ ⎥ 1 ⎞ (0.9 + 1) ⎥ I 20A (b) 0.04 = 0.025ln⎢⎜ = 10.1A → β FOR = 1.97 | I B = C = ⎟ ⎞ ⎛ β FOR 1.97 ⎢⎝ 0.4737 ⎠ 1− β FOR ⎥ ⎟ ⎜ ⎢⎣ ⎝ 15 ⎠ ⎥⎦ 140 5.61 With VBE = 0.7 and VBC = 0.5, the transistor is technically in the saturation region, but calculating the currents using the transport model in Eq. (5.13) yields ⎡ ⎛ 0.7 ⎞ ⎛ 0.5 ⎞⎤ 10−16 ⎡ ⎛ 0.5 ⎞ ⎤ iC = 10−16 ⎢exp⎜ ⎢exp⎜ ⎟ − exp⎜ ⎟⎥ − ⎟ −1⎥ = 144.5 μA 1 ⎣ ⎝ 0.025 ⎠ ⎦ ⎝ 0.025 ⎠⎦ ⎣ ⎝ 0.025 ⎠ ⎡ ⎛ 0.7 ⎞ ⎛ 0.5 ⎞⎤ 10−16 ⎡ ⎛ 0.7 ⎞ ⎤ −16 iE = 10 ⎢exp⎜ ⎢exp⎜ ⎟ − exp⎜ ⎟⎥ + ⎟ −1⎥ = 148.3 μA ⎝ 0.025 ⎠⎦ 39 ⎣ ⎝ 0.025⎠ ⎦ ⎣ ⎝ 0.025 ⎠ iB = 10−16 ⎡ ⎛ 0.7 ⎞ ⎤ 10−16 ⎡ ⎛ 0.5 ⎞ ⎤ ⎢exp⎜ ⎢exp⎜ ⎟ −1⎥ + ⎟ −1⎥ = 3.757 μA 39 ⎣ ⎝ 0.025⎠ ⎦ 1 ⎣ ⎝ 0.025 ⎠ ⎦ At 0.5 V, the collector-base junction is not heavily forward biased compared to the base-emitter junction, and IC = 38.5IB ≅ β F IB . The transistor still acts as if it is operating in the forwardactive region. 5.62 (a) The current source will forward bias the base - emitter junction (VBE ≅ 0.7V ) and the collector - base junction will then be reverse biased (VBC ≅ −2.3V ). Therefore, the npn transistor is in the forward - active region. ⎛ 50 175x10−6 A ⎞ ⎛ VBE ⎞ ⎟ = 0.803 V IC = β F I B = I S exp⎜ ⎟ | VBE = 0.025ln⎜ −16 ⎜ ⎟ V 10 A ⎝ T ⎠ ⎝ ⎠ (b) Since I B = 175μA and IC = 0, IC < β F I B , and the transistor is saturated. ( ) 175x10−6 + 0 Using Eq. (5.53) : VBE = 0.025ln = 0.714 V | Using Eq. (5.54) with iC = 0, ⎡ ⎛ .5 ⎞⎤ −16 1 10 ⎢ + ⎜1− ⎟⎥ ⎣ 50 ⎝ 1.5 ⎠⎦ ⎛ 1 ⎞ ⎛ β + 1⎞ ⎛ 1.5 ⎞ VCESAT = 0.025ln⎜ ⎟ = 0.025ln⎜ R ⎟ = 0.025ln⎜ ⎟ = 27.5 mV ⎝ 0.5 ⎠ ⎝αR ⎠ ⎝ βR ⎠ 141 5.63 ⎡ ⎛v ⎞ ⎛ v ⎞⎤ I ⎡ ⎛ v ⎞ ⎤ iC = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ + S ⎢exp⎜ BC ⎟ −1⎥ ⎝ VT ⎠⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎡ ⎛v ⎞ ⎛ v ⎞⎤ I ⎡ ⎛ v ⎞ ⎤ iE = I S ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ + S ⎢exp⎜ BE ⎟ −1⎥ ⎝ VT ⎠⎦ β F ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ vBE > 4VT and vBC < −4VT ⎡ ⎛ v ⎞⎤ ⎛ 1 ⎞⎡ ⎛ vBE ⎞⎤ I S ⎡ ⎛ v BE ⎞⎤ iC ≅ I S ⎢exp⎜ BE ⎟⎥ and iE = I S ⎜1+ ⎢exp⎜ ⎟⎢exp⎜ ⎟⎥ = ⎟⎥ → iC ≅ α F iE ⎝ β F ⎠⎣ ⎝ VT ⎠⎦ α F ⎣ ⎝ VT ⎠⎦ ⎣ ⎝ VT ⎠⎦ ⎛i ⎞ ⎛α i ⎞ vBE ≅ VT ln⎜ C ⎟ = VT ln⎜ F E ⎟ ⎝ IS ⎠ ⎝ IS ⎠ 5.64 I SD = IS αF = 1 fA = 1.02 fA 0.98 5.65 Both transistors are in the forward - active region. For simplicity, assume VA = ∞. I = IC1 + I B1 + I B 2 | Since the transistors are identical and have the same VBE , IC 2 = IC 1 and I B1 = I B 2 | I = IC1 + 2I B1 = (β F + 2)I B1 | IC 2 = β F I B 2 = β F I B1 IC 2 = βF βF + 2 I= 25 25μA | IC 2 = 23.2 μA | See the Current Mirror in Chapter 15. 25 + 2 5.66 CD = IC 50x10−12 τF = IC = 2x10−9 IC (F) (a) 4 fF (b) 0.4 pF (c) 40 pF VT 0.025 5.67 Using Fig. 2.8 with N = 1018 cm2 cm2 , μ = 260 and μ = 100 n p v-s v-s cm3 W2 WB2 (a) npn : τ F = B = = 2Dn 2VT μn W2 WB2 = (b) pnp : τ F = B = 2D p 2VT μ p 142 (1x10 −4 cm ) 2 ⎛ cm2 ⎞ 2(0.025V )⎜260 ⎟ v - s⎠ ⎝ (1x10 −4 cm ) = 0.769 ns 2 ⎛ cm2 ⎞ 2(0.025V )⎜100 ⎟ v - s⎠ ⎝ = 2.00 ns 5.68 For f >> f β , f T = β ⋅ f = 10(75MHz)= 750 MHz | f β = fT βF = 750 MHz = 3.75 MHz 200 5.69 f T 900 MHz f 900 MHz = = 180 | For f >> 5 MHz, β (f ) = T = = 18 5MHz 50 MHz fβ f βF = 5.70 6x1018 cm2 cm2 cm2 → μ = 130 using Fig. 2.8. D = μ V = 130 0.025V = 3.25 ( ) n n n T v−s v−s s cm3 2 ⎞⎛ 20 ⎞ ⎛ cm 10 1.60x10−19 C 25x10−8 cm 2 ⎜3.25 ⎟⎜ ⎟ 2 s ⎠⎝ cm6 ⎠ qADn ni ⎝ IS = = = 5.42x10−20 A 18 N AWB 6x10 0.4x10−4 cm cm3 NA = ( ) ( ) 5.71 WB = 2Dnτ F | τ F ≤ 18 1 1 = = 31.8 ps 2πf 2π 5x109 ( ) 2 5x10 cm → μn = 135 using Fig. 2.8. 3 v−s cm cm 2 cm2 0.025V = 3.38 Dn = μnVT = 135 ( ) v−s s ⎛ cm2 ⎞ −12 WB ≤ 2⎜ 3.38 ⎟31.8x10 s = 0.147 μm s ⎠ ⎝ NA = 5.72 ⎛ V ⎞ ⎛ ⎛ 10 ⎞ 265μA 5 ⎞ 240μA and β FO ⎜1+ ⎟ = IC = β F I B = β FO ⎜1+ CE ⎟ I B | β FO ⎜1+ ⎟ = 3μA 3μA ⎝ VA ⎠ ⎝ VA ⎠ ⎝ VA ⎠ ⎛ 10 ⎞ ⎜1+ ⎟ 80 ⎝ VA ⎠ 265μA = ⇒ VA = 43.1 V | β FO = = 71.7 ⎛ ⎛ 5 ⎞ 5 ⎞ 240μA ⎜1+ ⎟ ⎜1+ ⎟ ⎝ 43.1⎠ ⎝ VA ⎠ 5.73 143 ⎡ ⎛ V ⎞ ⎤⎛ V ⎞ ⎡ ⎛ 0.72V ⎞ ⎤⎛ 10V ⎞ ( a ) IC = I S ⎢exp⎜ BE ⎟ −1⎥⎜1+ CE ⎟ = 10−16 A⎢exp⎜ ⎟ −1⎥⎜1+ ⎟ = 371 μA ⎣ ⎝ 0.025V ⎠ ⎦⎝ 65V ⎠ ⎣ ⎝ VT ⎠ ⎦⎝ VA ⎠ ⎡ ⎛V ⎞ ⎤ ⎡ ⎛ 0.72V ⎞ ⎤ ( b ) IC = I S ⎢exp⎜ BE ⎟ −1⎥ = 10−16 A⎢exp⎜ ⎟ −1⎥ = 322 μA ⎣ ⎝ 0.025V ⎠ ⎦ ⎣ ⎝ VT ⎠ ⎦ ( c ) 1.15 :1 (a) is 15% larger than (b) due to the Early effect. 5.74 ⎛ V ⎞ IC = β F I B = β FO ⎜1+ CE ⎟ I B | We need two Q - points from the output characteristics. ⎝ VA ⎠ For example : (10 mA, 14 V) and (5 mA, 5 V) ⎛ 14 ⎞ ⎛ 5⎞ 10mA = β FO ⎜1+ ⎟0.1mA and 5mA = β FO ⎜1+ ⎟0.06mA yields ⎝ VA ⎠ ⎝ VA ⎠ ⎛ 14 ⎞ ⎛ 5⎞ 100 = β FO ⎜1+ ⎟ and 83.3 = β FO ⎜1+ ⎟. Solving these two equations yields ⎝ VA ⎠ ⎝ VA ⎠ β FO = 72.9 and VA = 37.6 V. 5.75 ⎡ ⎛ V ⎞ ⎤ ⎡ ⎛ V +V ⎞ ⎤ I ⎛V ⎞ BE Fig. 5.16(a) : I E = IC + I B = ⎢β FO ⎜1+ CE ⎟ + 1⎥ I B ≅ ⎢β FO ⎜1+ CB ⎟ + 1⎥ s exp⎜ BE ⎟ VA ⎠ ⎦ β FO ⎝ VT ⎠ ⎣ ⎝ VA ⎠ ⎦ ⎣ ⎝ ⎛ V ⎞ ⎡ 5 + VBE 1 ⎤ + ⎥ 5 x10−15 exp⎜ BE ⎟ = 100μA → VBE = 0.589V by iteration ⎢1+ 19 ⎦ 50 ⎣ ⎝ 0.025 ⎠ ⎛ 5.589 ⎞ 100μA = 4.52 μA | IC = 19⎜1+ IB = ⎟ I B = 95.48 μA ⎡ ⎛ 5.589 ⎞ ⎤ 50 ⎠ ⎝ ⎢19⎜1+ ⎟ + 1⎥ 50 ⎠ ⎦ ⎣ ⎝ ⎛V ⎞ 100μA For VA = ∞, I E = I s exp⎜ BE ⎟ | VBE = 0.025ln = 0.593 V 5 fA ⎝ VT ⎠ ( ) ⎛V ⎞ 19(100μA) exp⎜ BE ⎟ → VBE = 0.025ln = 0.667 V β FO 5 fA ⎝ VT ⎠ ⎛ V ⎞ ⎛ 5⎞ IC = β FO ⎜1+ CE ⎟ I B = 19⎜1+ ⎟100μA = 2.09 mA | I E = IC + I B = 2.19 mA ⎝ 50 ⎠ ⎝ VA ⎠ Fig. 5.16(b) : I B = Is VBE is independent of VA in the equation above. 5.76 144 ⎛ V ⎞ ⎛ 9 + 0.7 ⎞ IC = β F I B | I E = (β F + 1)I B | β F = β FO ⎜1+ CE ⎟ = 50⎜1+ ⎟ = 59.7 50 ⎠ ⎝ ⎝ VA ⎠ IE = (9 − 0.7)V = 1.01 mA | 8200Ω 5.77 I gm = C VT IE 1.01mA = = 16.7 μA | IC = 59.7 I B = 0.996 mA βF + 1 60.7 ( ) −23 kT 1.38x10 J / K (300K ) | VT = = = 25.9 mV q 1.60x10−19 C m = 10−5 A 10−4 A = 0.387 mS (b) g m = = 3.87 mS VT VT m = 10−3 A 10−2 A = 38.7 mS (d ) g m = = 0.387 S VT VT (a) g (c) g IB = (e) The values of g m are the same for the pnp. 5.78 IC 10x10−12 CD = τ F = IC = 3.88x10−10 IC (F) (a) 0.388 fF (b) 0.388 pF (c) 3.88 pF VT 0.0258 5.79 The following are from the Cadence website and the file psrefman.pdf: IS = 10fA, BF = 100, BR = 1, VAF = ∞, VAR = ∞, TF = 0, TR = 0, NF = 1, NE = 1.5, RB = 0, RC = 0, RE = 0, ISE = 0, ISC = 0, ISS = 0, IKF = ∞, IKR = ∞, CJE = 0, CJC = 0. These default values apply to both npn and pnp transistors. 5.80 ⎡ ⎛ i ⎞⎤ ⎛ 1mA ⎞ 1+ ⎢1+ 4⎜ F ⎟⎥ 1+ 1+ 4⎜ ⎟ ⎝ IKF ⎠⎦ ⎝10mA ⎠ ⎣ = = 1.09 → 8.3% reduction (a) KBQ = 2 2 ⎛ 10mA ⎞ 1+ 1+ 4⎜ ⎟ ⎝ 10mA ⎠ i = 1.62 | iC = F = 0.62iF → 38% reduction (a) KBQ = 2 1.62 ⎛ 50mA ⎞ 1+ 1+ 4⎜ ⎟ ⎝ 10mA ⎠ i = 2.79 | iC = F = 0.36iF → 64% reduction (a) KBQ = 2 2.79 NK 5.81 145 12.000 10.000 8.000 6.000 Series1 4.000 2.000 0.000 0.1 1 10 100 1000 Collector Current 5.82 36kΩ 10V = 3.462V | REQ = 36kΩ 68kΩ = 23.54kΩ 36kΩ + 68kΩ 3.462 − 0.7 V IB = = 1.618μA | IC = 50I B = 80.9 μA | I E = 51I B = 82.5 μA 23.54 + (50 + 1)33 kΩ (a) VEQ = VCE = 10 − 43000IC − 33000I E = 3.797V | Q - point : (80.9 μA,3.80 V) 7.2kΩ 10V = 3.462V | REQ = 7.2kΩ 13.6kΩ = 4.708kΩ 7.2kΩ + 13.6kΩ 3.462 − 0.7 V IB = = 8.092μA | IC = 50I B = 404.6μA | I E = 51I B = 412.7 μA 4.708 + (50 + 1)6.6 kΩ (b) VEQ = VCE = 10 − 8600IC − 6600I E = 3.7976V | Q - point : (405 μA,3.80 V) 68kΩ 10V = 6.538V | REQ = 36kΩ 68kΩ = 23.54kΩ 36kΩ + 68kΩ 10 − 0.7 − 6.538 V = 1.618μA | IC = 50I B = 80.9 μA | I E = 51I B = 82.5 μA IB = 23.54 + (50 + 1)33 kΩ (c) VEQ = VEC = 10 − 33000IC − 43000I E = 3.797V | Q - point : (80.9 μA,3.80 V) 13.6kΩ 10V = 6.538V | REQ = 7.2kΩ 13.6kΩ = 4.708kΩ 7.2kΩ + 13.6kΩ 10 − 0.7 − 6.538 V = 8.092μA | IC = 50I B = 404.6μA | I E = 51I B = 412.7 μA IB = 4.708 + (50 + 1)6.6 kΩ (b) VEQ = VEC = 10 − 6600IC − 8600I E = 3.7976V | Q - point : (405 μA,3.80 V) 5.83 146 36kΩ 10V = 3.462V | REQ = 36kΩ 68kΩ = 23.54kΩ 36kΩ + 68kΩ V 3.462 − 0.7 = 1.629μA | IC = 75I B = 122.2μA | I E = 76I B = 123.8μA IB = 23.54 + (75 + 1)22 kΩ (a) VEQ = VCE = 10 − 43000IC − 22000I E = 2.022V | Q - point : (122μA,2.02V) 68kΩ 10V = 6.538V | REQ = 36kΩ 68kΩ = 23.54kΩ 36kΩ + 68kΩ 10 − 0.7 − 6.538 V = 1.629μA | IC = 75I B = 122.2μA | I E = 76I B = 123.8μA IB = 23.54 + (75 + 1)22 kΩ (b) VEQ = VEC = 10 − 22000IC − 43000I E = 2.022V | Q - point : (122μA,2.02V) 5.84 *Problem 5.83(a) VCC 1 0 10 R1 3 0 36K R2 1 3 68K RC 1 2 43K RE 4 0 33K Q1 2 3 4 NPN .MODEL NPN NPN IS=1E-16 BF=50 BR=0.25 .OP .END *Problem 5.83(b) VCC 1 0 10 R1 3 0 36K R2 1 3 68K RC 1 2 43K RE 4 0 33K Q1 2 3 4 NPN .MODEL NPN NPN IS=1E-16 BF=50 BR=0.25 VAF=60 .OP .END *Problem 5.83(c) VCC 1 0 10 R1 1 3 36K R2 3 0 68K RC 4 0 43K RE 1 2 33K Q1 4 3 2 PNP .MODEL PNP PNP IS=1E-16 BF=50 BR=0.25 .OP .END *Problem 5.83(d) VCC 1 0 10 147 R1 1 3 36K R2 3 0 68K RC 4 0 43K RE 1 2 33K Q1 4 3 2 PNP .MODEL PNP PNP IS=1E-16 BF=50 BR=0.25 VAF=60 .OP .END 5.85 6.2 kΩ = 3.41V and REQ = 6.2 kΩ 12 kΩ = 4.09 kΩ 6.2kΩ + 12 kΩ 3.41− 0.7 IC = β F I B = 100 = 0.356 mA. 4090 + 101(7500) VEQ = 10 101 0.356 mA(7.5kΩ)= 5.49V 100 Q − po int : (0.356 mA, 5.49 V ) VCE = 10 − 0.356 mA(5.1kΩ)− 5.86 120 kΩ = 5.00V and REQ = 120 kΩ 240 kΩ = 80 kΩ 120kΩ + 240 kΩ 5.00 − 0.700 IC = β F I B = 100 = 42.2μA. 80000 + 101(100000) VEQ = 15 ( ) VCE = 15 − 42.2 x10−6 A 105 Ω − Q − po int : (42.2 μA, 4.39 V ) 5.87 (a) I E = ( ) 101 42.2 x10−6 A 1.5 x105 Ω = 4.39V 100 ⎛ 101⎞ 2V =⎜ = 1.98kΩ → 2.0 kΩ ⎟1mA = 1.01mA | RE = 1.01mA α F ⎝ 100 ⎠ IC RC = (12 − 5 − 2)V = 5kΩ → 5.1 kΩ R2 = (12 − 2.7)V = | VB = 2 + 0.7 = 2.7V 1.00mA V 2.7V = 27kΩ → 27 kΩ Set R1 = B = 10I B 10(0.01mA) 148 11I B 9.3V = 84.55kΩ → 82 kΩ 11(0.01mA) 27kΩ 12V = 2.972V | REQ = 27kΩ 82kΩ = 20.31kΩ 27kΩ + 82kΩ V 2.972 − 0.7 = 10.22μA | IC = 100I B = 1.022mA | I E = 101I B = 1.033mA IB = 20.31+ (100 + 1)2 kΩ (b) VEQ = VCE = 12 − 5100IC − 2000I E = 4.723V | Q - po int : (1.02mA,4.72V ) 5.88 ⎛ 76 ⎞ = ⎜ ⎟10μA = 10.13μA | Let VRC = VR E = VCE = 6V α F ⎝ 75 ⎠ 6V = 592kΩ → 620 kΩ RE = 10.13μA 6V = 600kΩ → 620 kΩ | VB = 6 + 0.7 = 6.7V RC = 10μA V 6.7V = 5.03MΩ → 5.1 MΩ Set R1 = B = ⎛ 10I B 10μA ⎞ 10⎜ ⎟ ⎝ 75 ⎠ (a) I E IC = (18 − 6.7)V = 11.3V = 7.71MΩ → 7.5 MΩ ⎛10μA ⎞ 11I B 11⎜ ⎟ ⎝ 75 ⎠ 5.1MΩ 18V = 7.286V | REQ = 5.1MΩ 7.5MΩ = 3.036 MΩ (b) VEQ = 5.1MΩ + 7.5MΩ 7.286 − 0.7 V = 0.1313μA | IC = 75I B = 9.848μA | I E = 76I B = 9.980μA IB = 3036 + (75 + 1)620 kΩ R2 = VCE = 18 − 620000IC − 620000I E = 5.707V | Q - point : (9.85 μA, 5.71 V) 5.89 (a) I RC = E (5 − 2 −1)V = 2.35kΩ → 2.4 kΩ 850μA Set R1 = R2 = ⎛ 61 ⎞ 1V = ⎜ ⎟850μA = 864.2μA | RE = = 1.16kΩ →1.2 kΩ 864.2μA α F ⎝ 60 ⎠ IC = VR1 10I B VR 2 11I B = = | VB = 5 −1− 0.7 = 3.3V 5 − 3.3V = 12.0kΩ →12 kΩ ⎛ 850μA ⎞ 10⎜ ⎟ ⎝ 60 ⎠ 3.3V = 21.2kΩ → 22 kΩ ⎛ 850μA ⎞ 11⎜ ⎟ ⎝ 60 ⎠ 149 22kΩ 5V = 3.24V | REQ = 12kΩ 22kΩ = 7.77kΩ 12kΩ + 22kΩ 5 − 0.7 − 3.24 V = 13.1μA | IC = 60I B = 786μA | I E = 61I B = 799μA IB = 7.77 + (60 + 1)1.2 kΩ (b) VEQ = VCE = 5 −1200I E − 2400IC = 2.14V | Q - point : (786 μA, 2.14 V) 5.90 11mA = 0.220mA 50 ⎛ 51 ⎞ I 1V I E = C = ⎜ ⎟11mA = 11.22mA | RE = = 89.1Ω → 91 Ω α F ⎝ 50 ⎠ 11.22mA (a ) V RE = 1 V ,VRC = 9 V | I B = 9V = 818Ω → 820 Ω | VB = −15 + 1+ 0.7 = −13.3V 11.0mA −13.3V − (−15V ) V Set R1 = R1 = = 772Ω → 750 Ω 10I B 10(0.220mA) RC = R2 = 0 − (13.3V ) 11I B = 13.3V = 5.50kΩ → 5.6 kΩ 11(0.220mA) 5.6kΩ (−15V )= −13.2V | REQ = 0.75kΩ 5.6kΩ = 0.661kΩ 0.75kΩ + 5.6kΩ −13.2 − 0.7 − (−15) V = 0.207mA | IC = 50I B = 10.3mA | I E = 51I B = 10.6mA IB = 661+ (50 + 1)(91) Ω (b) VEQ = VEC = 0 − 820IC − 91I E − (−15V ) = 5.59V | Q - point : (10.2 mA, 5.59 V) 5.91 Problem numbers on graph 3.3kΩ VEQ = 10V = 3.056V | REQ = 7.5kΩ 3.3kΩ = 2.292kΩ 3.3kΩ + 7.5kΩ VCE = 10 − 820IC −1200I E | From characteristics at VCE = 5V : β F ≅ 5mA = 83 60μA 84 IC = 10 - 2034IC 83 Load line points : IC = 0, VCE = 10V and VCE = 0, IC = 4.9mA VCE = 10 − 820IC −1200 IB = 3.056 − 0.7 = 23μA | From Graph : Q - point : (1.9 mA, 6.0 V) 2292 + (83 + 1)1200 150 10mA IB = 100 C o l l e c t o r 5mA Q-Point Prob. 5.92 IB = 92 μA μA I = 80 μA B IB = 60 μA C u r r e n t I = 40 μA B IB = 23 μA IB = 20 μA Q-Point Prob. 5.91 0A 0V 5V VCE 10V 15V 5.92 VEQ = 6.8kΩ (10)= 6.538V | REQ = 6.8kΩ 3.6kΩ = 2.354kΩ 6.8kΩ + 3.6kΩ VEC = 10 − 420IC − 330I E | From characteristics at VEC = 5V : β F ≅ VEC = 10 − 420IC − 3300 5mA = 83 60μA 84 IC = 10 − 754IC 83 Load line points : IC = 0, VEC = 10V and VEC = 0, IC = 13.3mA − off the graph VEC = 5V , IC = 6.63mA | I B = 10 − 0.7 − 6.538 = 92μA 2354 + (83 + 1)330 From Graph : Q - point : (7.5 mA, 4.3 V) 151 5.93 Writing a loop equation starting at the 9 V supply gives: 9 = 1500(IC + IB ) + 10000IB + VBE Assuming forward-active region operation, VBE = 0.7 V and IC = βFIB. 9 = 1500(β F I B + I B )+ 10000I B + 0.7 β F (9 − 0.7) 9 − 0.7 and IC = β F I B = 1500(β F + 1)+ 1000 1500(β F + 1)+ 1000 IB = (a ) I C (b) I (c) I = C = C = (d ) I C 30(9 − 0.7)V 1.5kW(30 + 1)+ 10kW 100(9 − 0.7)V 1.5kΩ(100 + 1)+ 10kΩ 250(9 − 0.7)V 1.5kΩ(250 + 1)+ 10kΩ = (9 − 0.7)V = 5.53 mA 1500Ω = 4.41 mA | VCE = 9 −1500I E = 2.17V | Q - pt : (4.41mA,2.17V) = 5.14 mA | VCE = 9 −1500I E = 1.21V | Q - pt : (5.14mA,1.21V) = 5.37 mA | VCE = 9 −1500I E = 0.913V | Q - pt : (5.37mA,0.913V) | VCE = 9 −1500I E = 0.705V | Q - pt : (5.53mA,0.705V) 5.94 ⎛ I ⎞ V − 0.7 VCE = 9 − (IC + I B )1500 | VCE = 9 − ⎜ IC + C ⎟1500 | I B = CE 4 βF ⎠ 10 ⎝ 5mA From Fig. P5.26 at 5V : β F = = 83.3 | VCE = 9 −1518IC 60μA IC = 0, VCE = 9V | VCE = 0, IC = 5.93mA VCE = 0.9V , I B = 20μA | VCE = 1.3V , I B = 60μA | VCE = 1.7V , I B = 100μA From graph : Q - point = (5.0 mA, 1.3 V) 10mA IB = 100 I = 100 B μA μA VCE = 1.7 V I = 80 μA B Collector Current IB = 80 μA VCE = 1.5 V 5mA IB = 60 μA Q-Point IB = 60 μA VCE = 1.3 V IB = 40 μA IB = 40 μA V CE = 1.1 V IB = 20 μA I = 20 μA B V CE = 0.9 V 0A 0V 5V V CE 152 10V 15V 5.95 (a) VEC = 10 − (IC + I B )RC = 10 − I E RC | I E = RC = (10 − 3)V = 689Ω → 680 Ω 10.17mA | RB = IC αF = 61 βF + 1 IC = 10mA = 10.17mA 60 βF VEC − VEB (3 − 0.7)V = = 13.8kΩ →14 kΩ 0.1667mA IB (b) 5 − 0.7 −14000I B − 680(IC + I B )− (−5)= 0 IB = 10 − 0.7 V = 222.1μA | IC = β F I B = 8.88 mA 14000 + 41(680) Ω VEC = 10V − (8.88mA)680Ω = 3.96 V | Q - po int : (8.88 mA, 3.96 V ) 5.96 VCE = 1.5 − (IC + I B )RC → RC = RB = 1.5 − 0.9 = 29.4kΩ → 30 kΩ 20μA 20μA + 50 VCE − VBE 0.9 − 0.65 = = 625kΩ → 620 kΩ 20μA IB 50 For RC = 30kΩ : VCE = 1.5 − 30kΩ(IC + I B )RC = 1.5 − 30kΩ(126)I B | I B = VCE − 0.65 620kΩ V − 0.65 VCE = 1.5 − 30kΩ(126) CE → VCE = 0.770V 620kΩ 0.770 − 0.65 IC = 125I B = 125 = 24.2μA | Q - po int : (24.2 μA, 0.770 V ) 620kΩ 5.97 12 = RC (IC + I B )+ VZ + VBE = 500(I E )+ 7.7 | I E = IB = 12 − 7.7 = 8.60mA 500 IE 8.60mA = = 85.2μA | IC = β F I B = 8.52mA | VCE = 7.70V 101 βF + 1 Q - point = (8.52 mA, 7.70 V) 5.95 15− 6 = 6.114V | REQ = 100Ω 7800Ω = 98.73Ω 7800+ 100 20mA VO 20mA 6.14 − 98.7I B − VBE 101.1− VBE + = + → I C = 50I B = 50 IB = 51 51 51(4700Ω) 51(4700Ω) 2.398x105 VEQ = 6+ 100 VBE = 0.025ln IC 10−16 153 Using MATLAB: fzero('IC107',.02) ---> ans =0.0207 function f=IC107(ic) vbe=0.025*log(ic/1e-16); f=ic-50*(101.1-vbe)/2.398e5; VO = 6.14 − 98.7 20.7mA 20.7mA − .025ln = 5.276 V 51 10−16 5.99 *Problem 5.98 VCC 1 0 DC 15 R1 1 2 7.8K RZ 2 4 100 VZ 4 0 DC 6 Q1 1 2 3 NPN RE 3 0 4.7K IL 3 0 20MA .MODEL NPN NPN IS=1E-16 BF=50 BR=0.25 .OP .END Output voltages will differ slightly due to different value of VT. 5.100 vO = 7 −100iB − vBE = 7 −100iB − VT ln vO = 7 −100iB − VT ln iL − VT ln iC α i = 7 −100iB − VT ln F L IS IS αF IS ⎛ dv di V ⎞ 100Ω 0.025V Ro = − O = −⎜ −100Ω B − T ⎟ = + = 3.21Ω 51 0.02 A diL diL iL ⎠ ⎝ 5.101 Since the voltage across the op - amp input must be zero, vO = VZ = 10 V. Since the input current to the op amp is zero, I E = I +15 = I Z + IC = I Z + α F I E = 154 VO = 100 mA 100 15V −10V 60 + 100mA = 98.5 mA 47kΩ 61 5.102 47Ω = VZ 47Ω + 47Ω and vO = 10 V. Since the input current to the op amp is zero, I 10V ⎛ 41⎞ 15V − 5V + 109mA = 109 mA IE = C = ⎜ ⎟ = 109 mA I +15 = I Z + I E = α F 94Ω ⎝ 40 ⎠ 82kΩ Since the voltage across the op - amp input must be zero, vO 5.103 IC = β F I B = β F VEQ − VBE REQ + (β F + 1)RE | For ICmin : VCC = 0.95(15) = 14.25 V R1 = 0.95(82kΩ)= 77.9kΩ | R2 = 1.05(120kΩ)= 126kΩ | RE = 1.05(6.8kΩ)= 7.14kΩ 77.9 14.25V = 5.44V | REQ = 77.9kΩ 126kΩ = 48.1kΩ 77.9 + 126 5.44V − 0.7V = 100 = 616 μA 48.1kΩ + (101)7.14kΩ VEQ = ICmin [ ] VCEmax = 14.25 − ICmin 0.95(6.8kΩ) − I Emin 7.14kΩ VCEmax = 14.25 − 3.98 − 4.44 = 5.83V | Q - po int : (616 μA, 5.83 V ) For ICmax : VCC = 1.05(15) = 15.75 V R1 = 1.05(82kΩ) = 86.1kΩ | R2 = 0.95(120kΩ)= 114kΩ | RE = 0.95(6.8kΩ)= 6.46kΩ 86.1 15.75V = 6.78V | REQ = 86.1kΩ 114kΩ = 49.0kΩ 86.1+ 114 6.78V − 0.7V = 100 = 867μA 49.0kΩ + (101)6.46kΩ VEQ = ICmax [ ] VCEmin = 15.75 − ICmax 1.05(6.8kΩ) − I Emax 6.46kΩ VCEmin = 15.75 − 6.19 − 5.66V = 3.90V | Q - po int : (867 μA, 3.90 V ) 155 5.104 Using the Spreadsheet approach in Fig. 5.40, Eq. set (5.66) becomes: ( ) ( ) = 6800 (1+ 0.1 (RAND() − 0.5)) 1. VCC = 15 1+ 0.1 (RAND() − 0.5) 3. R2 = 120000 1+ 0.1 (RAND() − 0.5) | 4. RE 5. RC = 6800 1+ 0.1 (RAND() − 0.5) β F = 100 ( ( | ) ) | 6. 500 Cases IC (A) VCE (V) Average Std. Dev. Min Max 7.69E-04 4.02E-05 6.62E-04 8.93E-04 4.51 0.40 3.31 5.55 5.105 IC = β F I B = β F VEQ − VBE REQ + (β F + 1)RE 2. R1 = 82000 1+ 0.1 (RAND() − 0.5) | For ICmin : VCC = 0.95(12) = 11.4 V R1 = 0.95(18kΩ) = 17.1kΩ | R2 = 1.05(36kΩ) = 37.8kΩ | RE = 1.05(16kΩ)= 16.8kΩ 17.1 11.4V = 3.55V | REQ = 17.1kΩ 37.8kΩ = 11.8kΩ 17.1+ 37.8 3.55V − 0.7V = 50 = 164 μA 11.8kΩ + (51)16.8kΩ VEQ = ICmin [ ] VCEmax = 11.4 − ICmin 0.95(22kΩ) − I Emin16.8kΩ VCEmax = 11.4 − 3.43 − 2.81 = 5.16V | Q - po int : (164 μA, 5.16 V ) For ICmax : VCC = 1.05(12) = 12.6 V R1 = 1.05(18kΩ) = 18.9kΩ | R2 = 0.95(36kΩ)= 34.2kΩ | RE = 0.95(16kΩ)= 15.2kΩ 18.9 12.6V = 4.49V | REQ = 18.9kΩ 34.2kΩ = 12.2kΩ 18.9 + 34.2 4.49V − 0.7V = 150 = 246μA 12.2kΩ + (151)15.2kΩ VEQ = ICmax [ ] VCEmin = 12.6 − ICmax 1.05(22kΩ) − I Emax 15.2kΩ VCEmin = 12.6 − 5.68 − 3.77V = 3.15V | Q - po int : (246 μA, 3.15 V ) 500 Cases IC (A) VCE (V) Average Std. Dev. Min Max 156 2.02E-04 1.14E-05 1.71E-04 2.35E-04 4.26 0.32 3.43 5.21 The averages are close to the hand calculations that go with Fig. 5.35. The minimum and maximum values fall within the worst-case analysis as we expect. 5.106 Using the Spreadsheet approach with zero tolerance on the current gain, Eq. set (5.66) becomes: ( ) 1. VCC = 12 1+ 0.0 (RAND() − 0.5) | 3. R2 = 36000 1+ 0.1 (RAND() − 0.5) | 4. 5. RC ( ) = 22000 (1+ 0.1 (RAND() − 0.5)) 500 Cases IC (A) VCE (V) Average Std. Dev. Min Max 2.03E-04 1.10E-05 1.74E-04 2.36E-04 4.29 0.32 3.46 5.27 ( ) R = 16000 (1+ 0.1 (RAND() − 0.5)) β = 100 (1+ 0.0(RAND() − 0.5)) R1 = 18000 1+ 0.1 (RAND() − 0.5) 2. E | 6. F Note that the current gain tolerance has little effect on the results. 5.107 (a) Approximately 22 cases fall outside the interval [170μA,250μA]: 100% (b) Approximately 125 cases fall inside the interval [3.2V,4.8V]: 100% 22 = 4.4% fail 500 125 = 25% fail 500 5.108 Using the Spreadsheet approach with 50% tolerance on the current gain, a tolerance TP on VCC, and a tolerance TR on resistor values, Eq. set (5.66) becomes: 1. VCC = 12 * (1+ 2 * TP * (RAND() − 0.5)) 3. R2 = 36000 * (1+ 2 * TR * (RAND() − 0.5)) | | 2. 4. R1 = 18000 * (1+ 2 * TR * (RAND() − 0.5)) RE = 16000 * (1+ 2 * TR * (RAND() − 0.5)) 5. RC = 22000 * (1+ 2 TR (RAND() − 0.5)) | 6. β F = 100 * (1+ 1* (RAND() − 0.5)) 10,000 case Monte Carlo runs indicate that the specifications cannot be achieved even with ideal resistors. For TP = 5% and TR = 0%, 18 % of the circuits fail. With TP = 2% and TR = 0%, 1.5% percent fail. The specifications can be met with TP = 1% and TR = 1%. 157 5.109 IC = β F I B = β F VEQ − VBE REQ + (β F + 1)RE | For ICmin : VCC = 0.95(12) = 11.4 V R1 = 0.8(18kΩ) = 14.4kΩ | R2 = 1.2(36kΩ)= 43.2kΩ | RE = 1.2(16kΩ)= 19.2kΩ 14.4 11.4V = 2.85V | REQ = 14.4kΩ 43.2kΩ = 10.8kΩ 14.4 + 43.2 2.85V − 0.7V = 50 = 109 μA 10.8kΩ + (51)19.2kΩ VEQ = ICmin [ ] VCEmax = 11.4 − ICmin 0.8(22kΩ) − I Emin19.2kΩ VCEmax = 11.4 −1.91− 2.13 = 7.36V | Q - point : (109 mA, 7.36 V) For ICmax : VCC = 1.05(12) = 12.6 V R1 = 1.2(18kΩ)= 21.6kΩ | R2 = 0.80(36kΩ)= 28.8kΩ | RE = 0.80(16kΩ)= 12.8kΩ 21.6 12.6V = 5.40V | REQ = 21.6kΩ 28.8kΩ = 12.3kΩ 21.6 + 28.8 5.4V − 0.7V = 150 = 362μA 12.3kΩ + (151)12.8kΩ VEQ = ICmax [ ] VCEmin = 12.6 − ICmax 1.2(22kΩ) − I Emax 12.8kΩ VCEmin = 12.6 − 9.57 − 4.67V = −1.64V! Saturated! The forward - active region assumption is violated. See the next problem. Based upon a Monte Carlo analysis, only about 1% of the circuits actually have this problem, although VCE will be relatively small in many circuits. 158 5.110 Using the Spreadsheet approach: 1. VCC = 12 * (1+ .1* (RAND() − 0.5)) | 2. 3. R2 = 36000 * (1+ 0.4 * (RAND() − 0.5)) | 4. 5. RC = 22000 * (1+ 0.4 * (RAND() − 0.5)) 7. VA = 75 * (1+ 0.66 * (RAND() − 0.5)) R1 = 18000 * (1+ 0.4 * (RAND() − 0.5)) | 6. RE = 16000 * (1+ 0.4 * (RAND() − 0.5)) β F = 100 * (1+ 1* (RAND() − 0.5)) In order to avoid an iterative solution at each step, assume that VCE does not influence the base current. Then, IB = VEQ − 0.7 and VCE REQ + (β FO + 1)RE ⎛ R ⎞ VCC − β FO IB ⎜ RC + E ⎟ ⎛ V ⎞ αF ⎠ ⎝ = | IC = β FO IB ⎜1+ CE ⎟ ⎛ β R ⎞ ⎝ VA ⎠ 1+ FO IB ⎜ RC + E ⎟ VA ⎝ αF ⎠ 500 Cases VCE (V) IC (A) Average Std. Dev. Min** Max 3.81E+00 1.26E+00 -2.07E-01 6.94E+00 2.049E-04 3.785E-05 1.264E-04 3.229E-04 **Note: In this particular simulation, there were 4 cases in which the transistor was saturated. 159 CHAPTER 6 6.1 (a ) Pavg = 1W 10-5W / gate = 10 μW / gate (b) I = = 4 μA / gate 105 gates 2.5V 6.2 (a) Pavg = 100 5x10-6W / gate = 5 μ W / gate (b) I = = 2 μA/ gate 2.5V 2x10 7 gates (c) I total = 2 μA (2x10 gates)= 40 A gate 7 6.3 ⎛ 2.5 − 0 ⎞ 5 (a ) VH = 2.5 V | VL = 0 V | PVH = I R = 0 mW | PVL = ⎜ ⎟ 10 = 62.5 μW 5 ⎝ 10 ⎠ 2 2 ⎛ 3.3 − 0 ⎞ 5 (b) VH = 3.3 V | VL = 0 V | PVH = I R = 0 mW | PVL = ⎜ ⎟ 10 = 109 μW 5 ⎝ 10 ⎠ 2 2 6.4 vO VH (3.3 V) vI V (0V) L 1.1 V (V REF) 3.3V V+ 6.5 v O V H (3.3 V) vI V L (0V) 1.1 V (V REF) 3.3V V+ () Z= A =A 6-1 6.6 V REF vI AV 6.7 V H = 3 V | VL = 0 V | VIH = 2 V | VIL = 1 V | AV = dvO −3V = = −3 dv I 1V 6.8 V (3 V) H v O Slope = +9 1.5 V v V (0V) I 6.9 VOH = 5 V 1.5 V 1.67 V 1.33 V L 3V V + VIH = VREF = 2 V NM H = 5 − 2 = 3 V VOL = 0 V VIL = VREF = 2 V NM L = 2 − 0 = 2 V 6.10 We would like to achieve the highest possible noise margins for both states and have them be symmetrical. Therefore VREF = 3.3/2=1.65 V. 6.11 V H = 3.3 V | VL = 0 V | VIH = 1.8 V | VOL ≅ 0.25 V | VIL = 1.5 V | VIH ≅ 3.0 V NM H = 3.0 −1.8 = 1.2 V | NM L = 1.5 − 0.25 = 1.25 V 6.12 VH = 2.5 V | VL = 0.20 V 6-2 6.13 V H = −0.80 V | VL = −1.35 V 6.14 VIH = VOH − NM H = −0.8 − 0.5 = −1.3 V | VIL = NM L + VOL = 0.5 + (−2) = −1.5 V 6.15 -13 -4 -9 τP = PDP/P = 10 J/10 W = 10 s = 1 ns 6.16 4 x10-6W / gate 1W = μ = 1.60 μA / gate 4 W / gate ( b ) I = 2.5V 2.5 x105 gates (c) PDP = 2ns (4 μW ) = 8 fJ (a ) Pavg = 6.17 1μW / gate 100W = 1 μW / gate (b) I = = 0.4 μA / gate 8 2.5V 10 gates (c) PDP = 1ns (1μW ) = 1 fJ (a) Pavg = 6.18 PDP 250 100 Slope = 2 10 Slope = 1 1 P 1 10 50 100 6-3 6.19 dv (t ) dvc (t ) | v(t ) = RC c + vC (t ) | v(t ) = 1 for t ≥ 0 dt dt ⎛ t ⎞ ⎛ t ⎞ v(t ) = 1 − exp⎜ − ⎟ | 0.9 = 1 − exp⎜ − 90% ⎟ → t90% = − RC ln (0.1) ⎝ RC ⎠ ⎝ RC ⎠ ⎛ t ⎞ 0.1 = 1 − exp⎜ − 10% ⎟ → t10% = − RC ln (0.9 ) | tr = t90% − t10% = RC ln (9) = 2.20 RC ⎝ RC ⎠ ⎛ t ⎞ ⎛ t ⎞ (b) v(t ) = 0 vC (0 ) = 1 v(t ) = exp⎜ − ⎟ | 0.9 = exp⎜ − 90% ⎟ → t90% = − RC ln (0.9) ⎝ RC ⎠ ⎝ RC ⎠ ⎛ t ⎞ 0.1 = exp⎜ − 10% ⎟ → t10% = − RC ln (0.1) | t f = t10% − t90% = RC ln (9 ) = 2.20 RC ⎝ RC ⎠ (a ) v(t ) = i (t )R + vC (t ) | i (t ) = C 6.20 (a) VH = 2.5V | VL = 0.20V (b) V10% = VL + 0.1ΔV = 0.20 + 0.23 = 0.43V → t10% ≅ 23 ns for vO V90% = VL + 0.9ΔV = 0.20 + 2.07 = 2.27V → t90% ≅ 33 ns for vO → t r = 33 − 23 = 10 ns For fall time : t10% ≅ 2.5 ns for vO t90% ≅ 0.8 ns for vO → t f = 1.7 ns For v I , t10% ≅ 0 ns t90% ≅ 1 ns t r = 1 ns | t f ≅ 1 ns (c) τ PHL ≅ 1.5ns − 0.5ns = 1 ns | τ PLH ≅ 26ns − 21ns = 5 ns (d ) τ P = 1+ 5 ns = 3 ns 2 6.21 (a) VH = −0.78V | VL = −1.36V (b) V10% = VL + 0.1ΔV = −1.36 + 0.1(0.58) = −1.30V → t10% ≅ 32.5 ns for vO V90% = VL + 0.9ΔV = −1.36 + 0.9(0.58) = −0.84V → t90% ≅ 42 ns for vO tr = 42 − 32.5 = 9.5 ns For fall time : t10% ≅ 11.5 ns for vO t90% ≅ 2 ns for vO → t f = 9.5 ns For vI , t10% ≅ 0 ns t90% ≅ 1 ns tr = 1 ns | t f ≅ 1 ns (c ) V50% = − 0.78 − 1.36 = −1.07V | τ PHL ≅ 4 ns | τ PLH 2 6-4 ≅ 4 ns (d ) τ P = 4+4 ns = 4 ns 2 6.22 (A + B)(A + C) AA + AC + BA + BC A + AC + BA + BC A(1 + C) + AB + BC A + AB + BC A(1+ B) + BC A + BC 6.23 Z = ABC + ABC + ABC Z = ABC + + ABC + ABC + ABC ( ) ( ) Z = AB C + C + A + A BC Z = AB(1) + (1)BC Z = AB + BC 6.24 A B C Z 0 0 0 0 0 1 0 0 0 0 1 1 1 0 0 1 0 0 1 0 1 1 1 0 1 1 1 0 1 0 1 1 Z = AB+BC 6-5 6.25 Z = ABC + ABC + ABC + ABC ( ) Z = C (AB + AB + AB + AB) Z = C (A(B + B)+ A(B + B)) Z = C (A(1) + A(1)) Z = C (A + A) Z = C AB + AB + AB + AB Z = C (1) Z =C 6.26 A B C 0 0 0 Z 0 0 0 1 1 0 1 0 0 0 1 1 1 1 0 0 0 1 0 1 1 1 1 0 0 1 1 1 Z =C 1 6-6 6.27 A B C D Z 0 0 0 0 0 0 0 0 1 0 0 0 1 0 0 0 0 1 1 0 0 1 0 0 0 0 1 0 1 0 0 1 1 0 0 0 1 1 1 0 1 0 0 0 0 1 0 0 1 0 1 0 1 0 0 1 0 1 1 0 1 1 0 0 0 1 1 0 1 0 1 1 1 0 0 1 1 1 1 1 6.28 A B C Z1 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 0 1 0 0 0 1 0 1 0 1 1 0 1 1 1 1 1 6.29 (a) Fanout = 2 Z = AB + CD ⎛ ⎞⎛ ⎞ Z = ⎜ AB⎟⎜CD⎟ ⎝ ⎠⎝ ⎠ Z = ABCD Z2 1 1 0 1 0 1 1 1 Z1 = AB = AB Z 2 = AB + C (b) Fanout = 1 6-7 6.30 i(t) 0.132 A For each line : i = C dv dt 3.3V = 132mA = 0.132 A 10− 9 s For all 64 lines, I = 64(0.132 A) = 8.45 A! i = 40 x10−12 F 1 ns t 0 6.31 i(t) 1.32 A For each line : i = C 3.3V = 1.32 A 10−10 s For all 64 lines, I = 64(1.32 A) = 84.5 A! i = 40 x10−12 F 0.1 ns t 0 dv dt 6.32 F ⎞⎛ 7.5mm 0.1cm ⎞ ⎛ 3.9⎜ 8.854 x10 −14 ⎟(1.5μm ) ⎟⎜ ⎛ ε ox A ⎞ 3.9ε o LW cm ⎠⎝ 2 mm ⎠ ⎝ ⎟⎟ = 3 = 0.583 pF C = 3⎜⎜ =3 1μm tox ⎝ tox ⎠ 6.33 CΔV KCox" WLΔV | Let W* = αW and L* = αL ΔT = = 1 I ⎛W ⎞ μ nCox" ⎜ ⎟(VGS − VTN )2 2 ⎝L⎠ C *ΔV * K (αW )(αL )(αΔV ) ΔT = = = α ΔT * 1 ⎛ αW ⎞ I 2 μn ⎜ ⎟(αVGS − αVTN ) 2 ⎝ αL ⎠ * V ε ⎛W ⎞ 2 ⎟(VGS − VTN ) = μ n ox ⎜ 2 Tox ⎝ L ⎠ αV ε ⎛ αW ⎞ 2 2 P* = μn ox ⎜ ⎟(αVGS − αVTN ) = α P 2 αTox ⎝ αL ⎠ P = VI = V ⎛W μ nCox" ⎜ 2 ⎝L PDP* = P*ΔT * = (αΔT )α 2 P = α 3 PΔT = α 3 PDP Power density = 6-8 P P P* α 2P P = | *= = A WL A αW (αL ) A ⎞ 2 ⎟(VGS − VTN ) ⎠ 6.34 1 1 ε ⎛W ⎞ ⎛W ⎞ μnCox" ⎜ ⎟(VGS − VTN )2 = μ n ox ⎜ ⎟(VGS − VTN )2 2 2 Tox ⎝ L ⎠ ⎝L⎠ ⎛W ⎞ ⎜ ⎟ ε 1 2 I D* = μn ox ⎜ 2 ⎟(VGS − VTN ) = 2 I D T L 2 ox ⎜ ⎜ ⎟⎟ 2 ⎝ 2 ⎠ (b) P* = V (2 I ) = 2VI = 2 P - The power has increased by a factor of two. ε ε W L CG (c) CG = Cox" WL = ox WL | CG* = ox = Tox 2 2 Tox 2 2 The capacitance has decreased by a factor of two. (a) I D = ⎛ W ⎞⎛ L ⎞ K ⎜ ⎟⎜ ⎟(ΔV ) ΔT C ΔV ⎝ 2 ⎠⎝ 2 ⎠ = (d ) ΔT * = = * 4 I ⎛W ⎞ 1 ⎜ 2 ⎟ 2 μ n ⎜ ⎟(VGS − VTN ) 2 ⎜ L ⎟ ⎜ ⎟ ⎝ 2 ⎠ * * 6.35 ( a ) Pavg = 6.36 (a) Pavg = ( 1W 6 0.5 2 x10 gates ) = 1 μW / gate ( b ) I = 1μW / gate = 0.556 μA / gate 1.8V 20W 1.5μW / gate = 1.5 μW / gate (b) I = = 0.833 μA/ gate ⎛2⎞ 1.8V 6 ⎜ ⎟20x10 gates ⎝ 3⎠ 6.37 V 2.5 - 0.2 50 μW = 20 μA | Let VL = TN = 0.2V | R = = 115 kΩ 2x10-5 2.5V 3 0.926 1 0.2 ⎞ ⎛W ⎞ ⎛W ⎞ ⎛ = M S is in the triode region : 20x10-6 = 60x10-6 ⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟0.2 → ⎜ ⎟ = 1 1.08 2 ⎠ ⎝ L ⎠S ⎝ L ⎠S ⎝ I DD = 6-9 6.38 (a ) For MS off, I D = 0 and VH = 2.5V. ⎛ ⎛ 3⎞⎛ μA ⎞ 2.5 − VL V ⎞ μA = Kn ⎜VH − VTN − L ⎟VL | Kn = ⎜ ⎟⎜60 2 ⎟ = 180 2 200kΩ 2⎠ V ⎝ ⎝ 1 ⎠⎝ V ⎠ ⎛ V ⎞ μA ⎞⎛ 2.5 − VL = 2x105 ⎜180 2 ⎟⎜2.5 − 0.6 − L ⎟VL → 36VL2 −138.8VL + 5 = 0 2⎠ V ⎠⎝ ⎝ 2.5 − 0.0364 = 12.3 μA | P = 2.5V (12.3 μA) = 30.8 μW VL = 0.0364 V | I D = 200kΩ 0.0364 ⎞ μA ⎛ Checking : I D = 180 2 ⎜ 2.5 − 0.6 − ⎟0.0364 = 12.3 μA 2 ⎠ V ⎝ (b) For MS off, I D = 0 and VH = 2.5V. For VL , I D = ( ) ⎛ ⎛ 6 ⎞⎛ μA ⎞ 2.5 − VL V ⎞ μA = Kn ⎜VH − VTN − L ⎟VL | Kn = ⎜ ⎟⎜60 2 ⎟ = 360 2 400kΩ 2⎠ V ⎝ ⎝ 1 ⎠⎝ V ⎠ ⎛ V ⎞ μA ⎞⎛ 2.5 − VL = 4x105 ⎜ 360 2 ⎟⎜2.5 − 0.6 − L ⎟VL →144VL2 − 549.2VL + 5 = 0 2⎠ V ⎠⎝ ⎝ 2.5 − 0.00913 = 6.23 μA | P = 2.5V (6.23 μA)= 15.6 μW VL = 9.13 mV | I D = 400kΩ 0.00913⎞ μA ⎛ Checking : I D = 360 2 ⎜ 2.5 − 0.6 − ⎟0.00913 = 6.21 μA 2 ⎠ V ⎝ For VL , I D = ( ) 6.39 (a ) For MS off, I D = 0 and VH = 2.5V. ⎛ ⎛ 3⎞⎛ μA ⎞ 2.5 − VL V ⎞ μA = Kn ⎜VH − VTN − L ⎟VL | Kn = ⎜ ⎟⎜60 2 ⎟ = 180 2 200kΩ 2⎠ V ⎝ ⎝ 1 ⎠⎝ V ⎠ ⎛ V ⎞ μA ⎞⎛ 2.5 − VL = 2x105 ⎜180 2 ⎟⎜2.5 − 0.8 − L ⎟VL → 36VL2 −124.4VL + 5 = 0 2⎠ V ⎠⎝ ⎝ 2.5 − 0.0407 = 12.3 μA | P = 2.5V (12.3 μA) = 30.7 μW VL = 0.0407 V | I D = 200kΩ 0.0407 ⎞ μA ⎛ Checking : I D = 180 2 ⎜ 2.5 − 0.8 − ⎟0.0407 = 12.3 μA 2 ⎠ V ⎝ For VL , I D = ( ) ⎛ μA ⎞⎛ (b) 2.5 − V = (2x10 )⎜⎝180 V 5 L VL ⎞ 2 2.5 − 0.4 − ⎟ ⎜ ⎟VL → 36VL −153.2VL + 5 = 0 2 2⎠ ⎠⎝ 2.5 − 0.0329 = 12.3 μA | P = 2.5V (12.3 μA) = 30.8 μW 200kΩ 0.0329 ⎞ μA ⎛ Checking : I D = 180 2 ⎜ 2.5 − 0.4 − ⎟0.0329 = 12.3 μA 2 ⎠ V ⎝ VL = 0.0329 V | I D = 6-10 6.40 (a) V IL = VTN + 1 1 1 = 0.6V + = 0.6 + = 0.627 V Kn R 36 3 ⎛ μA ⎞ ⎜ 60 ⎟(200kΩ) 1⎝ V 2 ⎠ VOH = VDD − 1 1 2VDD 5 = 2.5 − = 2.49V | VOL = = = 0.215V 3Kn R 2Kn R 72 108 VIH = VTN − 1 V 1 2.5 + 1.63 DD = 0.6 − + 1.63 = 1.00V Kn R 36 36 Kn R NM L = 0.627 − 0.215 = 0.412 V | NM H = 2.49 −1.00 = 1.49 V 1 1 1 = 0.6 + = 0.607 V (b) VIL = VTN + K R = 0.6V + 6 ⎛ μA⎞ 144 n ⎜ 60 ⎟(400kΩ) 1⎝ V2 ⎠ VOH = VDD − 1 1 2VDD 5 = 2.5 − = 2.50V | VOL = = = 0.108V 3Kn R 2Kn R 288 432 VIH = VTN − 1 V 1 2.5 + 1.63 DD = 0.6 − + 1.63 = 0.807V Kn R 144 144 Kn R NM L = 0.607 − 0.108 = 0.499 V | NM H = 2.50 − 0.807 = 1.69 V 6.41 (a ) For MS off, I D = 0 and VH = 2.5V. ⎛ ⎛ 6 ⎞⎛ μA ⎞ 2.5 − VL V ⎞ μA = Kn ⎜VH − VTN − L ⎟VL | Kn = ⎜ ⎟⎜60 2 ⎟ = 360 2 400kΩ 2⎠ V ⎝ ⎝ 1 ⎠⎝ V ⎠ ⎛ V ⎞ μA ⎞⎛ 2.5 − VL = 4x105 ⎜ 360 2 ⎟⎜2.5 − 0.6 − L ⎟VL →144VL2 − 549.2VL + 5 = 0 2⎠ V ⎠⎝ ⎝ 2.5 − 0.00913 = 6.23 μA | P = 2.5V (6.23 μA)= 15.6 μW VL = 9.13 mV | I D = 400kΩ 0.00913⎞ μA ⎛ Checking : I D = 360 2 ⎜ 2.5 − 0.6 − ⎟0.00913 = 6.23 μA 2 ⎠ V ⎝ ⎛ V ⎞ (b) 2.5 − VL = 144⎜⎝2.5 − 0.5 − 2L ⎟⎠VL →144VL2 − 578VL + 5 = 0 2.5 − 0.00867 = 6.33 μA | P = 2.5V (6.33 μA)= 15.8 μW VL = 8.67 mV | I D = 400kΩ μA ⎛ 0.00867 ⎞ Checking : I D = 360 2 ⎜ 2.5 − 0.5 − ⎟0.00867 = 6.23 μA 2 ⎠ V ⎝ For VL , I D = ( ) 6-11 (c) 2.5 − V L ⎛ V ⎞ = 144⎜2.5 − 0.7 − L ⎟VL →144VL2 − 520.4VL + 5 = 0 2⎠ ⎝ 2.5 − 0.00963 = 6.23 μA | P = 2.5V (6.23 μA)= 15.6 μW 400kΩ μA ⎛ 0.00963 ⎞ Checking : I D = 360 2 ⎜ 2.5 − 0.7 − ⎟0.00963 = 6.22 μA 2 ⎠ V ⎝ VL = 9.63 mV | I D = In this design, we see that VL is not sensitive to VTN. 6.42 (a) V IL = VTN + 1 1 1 = 0.6V + = 0.6 + = 0.607V Kn R 144 6 ⎛ μA ⎞ ⎜ 60 ⎟(400kΩ) 1⎝ V2 ⎠ VOH = VDD − 1 1 2VDD 5 = 2.5 − = 2.50V | VOL = = = 0.108V 2Kn R 288 432 3Kn R VIH = VTN − 1 V 1 2.5 + 1.63 DD = 0.6 − + 1.63 = 0.807V Kn R 144 144 Kn R NM L = 0.607 − 0.108 = 0.499 V | NM H = 2.50 − 0.807 = 1.69 V (b) V IL = 0.6 + 1 5 | VOL = | NM L = VIL-VOL = 0 Kn R 3Kn R Solving for Kn R yields no solution. Zero noise margin will not occur. 6.43 (a) I D = P 0.25mW V − VL 2.5 − 0.5 = = 100μA | R = DD = = 20.0 kΩ ID VDD 2.5V 1x10-4 Using the values corresponding to Fig. 6.12, K 'p = 100μA/V 2 ⎛W ⎞ ⎛ ⎛ W ⎞ 1.21 0.5 ⎞ 100μA = 100x10-6 ⎜ ⎟ ⎜2.5 − 0.6 − ⎟0.5 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S ( (b) V IL ) = VTN + 1 1 1 = 0.6V + = 0.6 + = 1.01 V ⎛ Kn R 2.42 μA ⎞ ⎜1.21x100 2 ⎟(20kΩ) V ⎠ ⎝ VOH = VDD − 1 1 2VDD 5 = 2.5 − = 2.29V | VOL = = = 0.830V 2Kn R 4.84 7.26 3Kn R VIH = VTN − 1 V 1 2.5 + 1.63 DD = 0.6 − + 1.63 = 1.84V Kn R 2.42 2.42 Kn R NM L = 1.01− 0.83 = 0.18 V | NM H = 2.29 −1.84 = 0.450 V 6-12 6.44 P 0.25mW V − VL 3.3 − 0.2 = = 75.76μA | R = DD = = 40.9 kΩ ID VDD 3.3V 75.76x10-6 ⎛W ⎞ ⎛ ⎛ W ⎞ 1.52 0.2 ⎞ 75.76x10-6 = 100x10-6 ⎜ ⎟ ⎜3.3 − 0.7 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S (a) I = D ( (b) V IL = VTN + ) 1 = 0.7V + Kn R 1 1 = 0.7 + = 0.861 V ⎛ 6.22 μA ⎞ (1.52)⎜⎝100 V 2 ⎟⎠(40.9kΩ) VOH = VDD − 1 1 2VDD 6.6 = 3.3 − = 3.22 | VOL = = = 0.594V 3Kn R 2Kn R 12.4 18.7 VIH = VTN − 1 V 1 3.3 + 1.63 DD = 0.7 − + 1.63 = 1.73V Kn R Kn R 6.22 6.22 NM L = 0.861− 0.594 = 0.267 V | NM H = 3.22 −1.73 = 1.49 V 6.45 VDD − VL 3 − 0.25 = = 83.3 kΩ ID 33x10-6 ⎛W ⎞ ⎛ ⎛ W ⎞ 1.04 0.25 ⎞ 33x10−6 = 60x10-6 ⎜ ⎟ ⎜3 − 0.75 − ⎟0.25 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S (a) R = ( ) (b) SPICE yields VL = 0.249 V with ID = 33.0 μA. 6.46 VDD − VL 2 − 0.15 = = 185 kΩ ID 10x10-6 ⎛W ⎞ ⎛ ⎛W ⎞ 0.15 ⎞ 1 10−5 = 75x10-6 ⎜ ⎟ ⎜2 − 0.6 − ⎟0.15 → ⎜ ⎟ = 2 ⎠ ⎝ L ⎠S ⎝ ⎝ L ⎠ S 1.49 (a) R = ( ) (b) SPICE yields VL = 0.15 V with ID = 10 μA. 6-13 6.47 1 1 = 417 Ω ⎛ ⎞ ' W −6 10 Kn (VGS − VTN ) 60x10 ⎜ ⎟(5 −1) L ⎝1⎠ 1 1 = = 1000 Ω (b) Ron = ⎛ ⎞ ' W −6 10 K p (VSG + VTP ) 25x10 ⎜ ⎟(5 −1) L ⎝1⎠ (c) A resistive connection exists between the source and drain. 1 1 20 W = ' = = (d ) −6 L Kn (VGS − VTN )Ron 60x10 (3 −1)(417) 1 (a) Ron = = W 1 1 20 = ' = = −6 L K p (VSG + VTP )Ron 25x10 (3 −1)(1000) 1 6.48 ( VH = VDD − VTO + γ (V H (V SB + 2φ F − 2φ F ))→ V H ( ( = 3.3 − 0.75 + 0.75 VH + 0.7 − 0.7 )) − 4.88) = 0.5625(VH + 0.7) → VH2 − 6.918VH + 9.706 = 0 2 VH = 4.962V , 1.956V → VH = 1.96 V ( ) Checking : VTN = 0.75 + 0.75 1.956 + 0.75 − 0.75 = 1.345V | VH = 3.3 −1.345 = 1.96V 6.49 ( VH = VDD − VTO + γ (V H (V SB + 2φ F − 2φ F ))→ V H )) 2 Checking : VTN = 0.5 + 0.6 6.50 ( VH = VDD − VTO + γ H ( − 3.165) = 0.36(VH + 0.6)→ VH2 − 6.69VH + 9.80 = 0 VH = 2.166V , 4.524V → VH = 2.17 V (V ( = 3.3 − 0.6 + 0.6 VH + 0.6 − 0.6 (V SB ( 2.166 + 0.6 − + 2φ F − 2φ F ) 0.6 = 1.133V | VH = 3.3 −1.133 = 2.167V ))→ V H ( ( = 2.5 − 0.5 + 0.85 VH + 0.6 − 0.6 )) − 2.659) = 0.7225(VH + 0.6)→ VH2 − 6.04VH + 6.634 = 0 2 VH = 1.444V , 4.596V → VH = 1.44 V ( ) Checking : VTN = 0.5 + 0.85 1.444 + 0.6 − 0.6 = 1.057V | VH = 2.5 −1.057 = 1.443V 6-14 6.51 For γ = 0, VH = VDD − VTN = 3.3 − 0.6 = 2.7V | For VL : I DL = I DS ⎛ ⎞⎛ 2 Kn' ⎛ 1 ⎞ VL ⎞ ' 4 2 ⎜ ⎟(3.3 − VL − 0.6) = Kn ⎜ ⎟⎜ 2.7 − 0.6 + − ⎟VL → 9VL − 39VL + 7.29 = 0 2 ⎝ 2⎠ 2⎠ ⎝ 1 ⎠⎝ 2 60x10−6 ⎛ 1 ⎞ VL = 0.1958V | I DD = ⎜ ⎟(3.3 − 0.1958 − 0.6) = 94.1μA 2 ⎝ 2⎠ P = (3.3V )(94.08μA)= 0.311 mW ⎛ 4 ⎞⎛ 0.1958 ⎞ Checking : I DD = 60x10−6⎜ ⎟⎜2.7 − 0.6 − ⎟0.1958 = 94.1μA 2 ⎠ ⎝ 1 ⎠⎝ 6.52 (a ) For γ = 0, VH = VDD − VTN = 3.3 − 0.8 = 2.5V | For VL : I DL = I DS ⎛ 4 ⎞⎛ 2 Kn' 1 V ⎞ 3.3 − VL − 0.8) = Kn' ⎜ ⎟⎜2.5 − 0.8 − L ⎟VL → 9VL2 − 32.2VL + 6.25 = 0 | VL = 0.206V ( 2 2 2⎠ ⎝ 1 ⎠⎝ 2 60x10−6 1 I DD = 3.3 − 0.206 − .8) = 78.9μA | P = 3.3V(78.9μA)= 0.260 mW ( 2 2 ⎛ 4 ⎞⎛ 0.206 ⎞ Checking : I DD = 60x10−6⎜ ⎟⎜2.5 − 0.8 − ⎟0.206 = 79.0μA 2 ⎠ ⎝ 1 ⎠⎝ (b) For γ = 0, VH = VDD − VTN = 3.3 − 0.4 = 2.9V | For VL : I DL = I DS ⎛ 4 ⎞⎛ 2 Kn' 1 V ⎞ 3.3 − VL − 0.4) = Kn' ⎜ ⎟⎜2.9 − 0.4 − L ⎟VL → 9VL2 − 45.8VL + 8.41 = 0 | VL = 0.191 V ( 2 2 2⎠ ⎝ 1 ⎠⎝ 2 60x10−6 1 3.3 − 0.191− 0.4) = 110μA | P = 3.3V(6.55μA)= 0.363 mW ( 2 2 ⎛ 4 ⎞⎛ 0.191⎞ Checking : I DD = 60x10−6⎜ ⎟⎜2.9 − 0.4 − ⎟0.191 = 110μA 2 ⎠ ⎝ 1 ⎠⎝ I DD = 6.53 VIL = VTNS = 0.6 V | VOH = VH = VDD − VTNL = 3.3 − 0.6 = 2.7V At VIH (See Eq. 6.29 Second Edition) VOL = VDD − VTNL 3.3 − 0.6 1+ 3KR = 0.540V 4 1+ 3 0.5 (VDD − VOL − VTNL ) = 0.6 + 0.54 + 0.5 1 3.3 − 0.54 − 0.6 2 = 1.41V V + OL + ( ) 2 2 2KRVOL 2(4) 0.54 2 VIH = VTNS NM H = 2.7 −1.41 = 1.29 V | NM L = 0.60 − 0.54 = 0.06 V These values are readily confirmed with SPICE. 6-15 4.0 2.0 0 -2.0 6.54 (a ) For γ = 0, VH = VDD − VTN = 3.3 − 0.6 = 2.7V | For VL : I DL = I DS ⎛ 8 ⎞⎛ 2 Kn' 1 V ⎞ 3.3 − VL − 0.6) = Kn' ⎜ ⎟⎜2.7 − 0.6 − L ⎟VL → 9VL2 − 39VL + 7.29 = 0 ( 2 1 2⎠ ⎝ 1 ⎠⎝ −6 ⎛ ⎞ 2 60x10 1 VL = 0.1958V | I DD = ⎜ ⎟(3.3 − 0.1958 − 0.6) = 188μA 2 ⎝ 1⎠ P = (3.3V )(188μA)= 0.621 mW ⎛ 8 ⎞⎛ 0.1958 ⎞ Checking : I DD = 60x10−6⎜ ⎟⎜2.7 − 0.6 − ⎟0.1958 = 188μA - check is ok 2 ⎠ ⎝ 1 ⎠⎝ (b) VIL = VTNS = 0.6 V | VOH = VH = VDD − VTNL = 3.3 − 0.6 = 2.7V At VIH (See Eq. 6.29 Second Edition) VOL = VDD − VTNL 3.3 − 0.6 1+ 3KR = 0.540V 4 1+ 3 0.5 (VDD − VOL − VTNL ) = 0.6 + 0.54 + 0.5 1 3.3 − 0.54 − 0.6 2 = 1.41V V + OL + ( ) 2 2KRVOL 2 2(4) 0.54 2 VIH = VTNS NM H = 2.7 −1.41 = 1.29 V | NM L = 0.60 − 0.54 = 0.06 V These values are easily checked with SPICE. See Prob. 6.53, (c) For γ = 0, VH = VDD − VTN = 3.3 − 0.7 = 2.6V | For VL : I DL = I DS ⎛ 8 ⎞⎛ 2 Kn' 1 V ⎞ 3.3 − VL − 0.7) = Kn' ⎜ ⎟⎜2.6 − 0.7 − L ⎟VL → 9VL2 − 32.2VL + 6.25 = 0 ( 2 1 2⎠ ⎝ 1 ⎠⎝ 2 60x10−6 1 3.3 − 0.200 − 0.7) = 173μA ( 1 2 P = (3.3V )(173μA)= 570 μW VL = 0.200V | I DD = ⎛ 8 ⎞⎛ 0.200 ⎞ Checking : I DD = 60x10−6⎜ ⎟⎜2.6 − 0.7 − ⎟0.200 = 173μA - check is ok 2 ⎠ ⎝ 1 ⎠⎝ 6-16 6.55 ( (a) VH = VDD − VTO + γ (V (V SB + 2φ F − 2φ F ))→ V H ( ( = 3.3 − 0.7 + 0.5 VH + 0.6 − 0.6 )) − 2.987) = 0.25(VH + 0.6)→ VH2 − 6.225VH + 8.772 = 0 → VH = 2.156 V 2 H VL = 0.20V | I D = ⎛W ⎞ ⎛ 0.25mW 0.20 ⎞ = 75.76μA | 75.76 = 100⎜ ⎟ ⎜ 2.156 − 0.7 − ⎟0.20 3.3V 2 ⎠ ⎝ L ⎠S ⎝ ⎛W ⎞ 2.79 | VTNL = 0.7 + 0.5 0.2 + 0.6 − 0.6 = 0.760V ⎜ ⎟ = 1 ⎝ L ⎠S ⎛W ⎞ 2 1 100 ⎛W ⎞ 75.76 = ⎜ ⎟ (3.3 − 0.20 − 0.760) → ⎜ ⎟ = 2 ⎝ L ⎠L ⎝ L ⎠ L 3.61 (b) VIL = VTNS = 0.70V | VOH = VH = 2.16V ( ) Finding VIH (See Eq 6.29 in 2nd Ed.) : VOL = VDD − VTNL 1+ 3 ( VTNL = 0.7 + 0.5 VOL + 0.6 − 0.6 )| (W / L) (W / L) S ( L = 3.3 − VTNL 1 + 3(2.79)(3.61) ( = 3.3 − VTNL 5.587 5.587VOL = 3.3 − 0.7 + 0.5 VOL + 0.6 − 0.6 )) Using the quadratic equation : VOL = 0.4432V → VTNL = 0.8234V VIH = VTNS + 2 VOL (W / L)L 1 + VDD − VOL − VTNL ) ( 2 (W / L) 2VOL S VIH = 0.7 + 2 0.443 1 ⎛ 1⎞ 1 + 3.3 − 0.443 − 0.823) | VIH = 1.39V ⎜ ⎟ ( 2 10.07 ⎝ 2 ⎠ 0.443 NM H = 2.16 − 1.39 = 0.77 V | NM L = 0.7 − 0.443 = 0.26 V 4.0 2.0 0 -2.0 6-17 6.56 ( ) 0.4mW = 160μA | VTNL = 0.6 + 0.5 0.3 + 0.6 − 0.6 = 0.687V 2.5V ⎛ W ⎞ 1.40 2 100x10−6 ⎛W ⎞ 160x10−6 = ⎜ ⎟ (2.5 − 0.3 − 0.687) → ⎜ ⎟ = 2 1 ⎝ L ⎠L ⎝ L ⎠L ⎛W ⎞ ⎛ ⎛W ⎞ 0.3 ⎞ 6.67 160x10−6 = 100x10−6 ⎜ ⎟ ⎜1.55 − 0.6 − ⎟0.3 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S I DD = 6.57 (a) VDD = 3.3 V VTN =1 V ID = 75 μA VL = 0.2 V VH = VDD - VTN = 3.3 V - 0.6V = 2.7 V +3.3 V + M V L DSL + GS - ID V = 3.1 V = 3.1 V VL = 0.2V + M V H = 2.7 V S V DSS = 0.2 V - I DS = I DL = 75μA ⎛W ⎞ ⎛ V ⎞ I DS = Kn' ⎜ ⎟ ⎜VGSS − VTHS − DSS ⎟VDSS 2 ⎠ ⎝ L ⎠S ⎝ 2 K ' ⎛W ⎞ I DL = n ⎜ ⎟ (VGSL − VTNL ) 2 ⎝ L ⎠L ( (b) VH = VDD − VTO + γ (V H (V SB 75μA = 75μA = 100 100 μA V2 2 + 2φ F − 2φ F μA ⎛W ⎞ ⎛ ⎛W ⎞ 1.88 0.2 ⎞ ⎜ ⎟ ⎜ 2.7 − 0.6 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 V ⎝ L ⎠S ⎝ ⎝ L ⎠S 2 ⎛W ⎞ ⎛W ⎞ 2 1 ⎜ ⎟ (3.3 − 0.2 − 0.6) → ⎜ ⎟ = ⎝ L ⎠L ⎝ L ⎠ L 4.17 ))→ V H ( ( = 3.3 − 0.6 + 0.5 VH + 0.6 − 0.6 − 3.087) = 0.25(VH + 0.6)→ VH2 − 6.424VH + 9.381 = 0 → VH = 2.245 2 ⎛W ⎞ 0.2 ⎞ 2.43 2.245 − 0.6 − 0.2 → ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ = 2 2 ⎠ 1 V ⎝ L ⎠S ⎝ ⎝ L ⎠S 2 K ' ⎛W ⎞ I DL = n ⎜ ⎟ (VGSL − VTNL ) | VTNL = 0.6 + 0.5 0.2 + 0.6 − 0.6 = 0.660V 2 ⎝ L ⎠L 75μA = 100 μA ⎛ W ⎞ ⎛ ( 75μA = 6-18 100 μA V2 2 ⎛W ⎞ ⎛W ⎞ 2 1 ⎜ ⎟ (3.3 − 0.2 − 0.66) → ⎜ ⎟ = ⎝ L ⎠L ⎝ L ⎠ L 3.97 ) )) 6.58 (a ) For γ = 0, V H = VDD − VTO = 2 − 0.6 = 1.4V ⎛W ⎞ ⎛ ⎛W ⎞ ⎛ ⎛W ⎞ V ⎞ 0.15⎞ 2.30 I DS = Kn' ⎜ ⎟ ⎜VH − VTNS − L ⎟VL | 25x10−6 = 100x10−6 ⎜ ⎟ ⎜1.4 − 0.6 − ⎟0.15 → ⎜ ⎟ = 2 ⎠ 1 2⎠ ⎝ L ⎠S ⎝ ⎝ L ⎠S ⎝ ⎝ L ⎠S ⎛W ⎞ 2 2 K ' ⎛W ⎞ 100x10−6 ⎛W ⎞ 1 I DL = n ⎜ ⎟ (VGSL − VTNL ) | 25x10−6 = ⎜ ⎟ (2 − 0.15 − 0.6) → ⎜ ⎟ = 2 ⎝ L ⎠L 2 ⎝ L ⎠L ⎝ L ⎠ L 3.13 (b) For γ = 0.6, V H [ )] ( = VDD − VTNL = 2 − 0.6 + 0.6 VH + 0.6 − 0.6 → VH = 1.09V ⎛W ⎞ ⎛ ⎛W ⎞ ⎛ ⎛W ⎞ V ⎞ 0.15 ⎞ 4.02 I DS = Kn' ⎜ ⎟ ⎜VH − VTNS − L ⎟VL | 25x10−6 = 100x10−6 ⎜ ⎟ ⎜1.09 − 0.6 − ⎟0.15 → ⎜ ⎟ = 2 ⎠ 1 2⎠ ⎝ L ⎠S ⎝ ⎝ L ⎠S ⎝ ⎝ L ⎠S ( 0.15 + 0.6 − For vO = VL = 0.15V , VTN = 0.6 + 0.6 ) 0.6 = 0.655V ⎛W ⎞ 2 2 Kn' ⎛W ⎞ 100x10−6 ⎛W ⎞ 1 −6 V − V | 25x10 = ⎜ ⎟ ( GSL TNL ) ⎜ ⎟ (2 − 0.15 − 0.655) → ⎜ ⎟ = 2 ⎝ L ⎠L 2 ⎝ L ⎠L ⎝ L ⎠ L 2.86 (c) Using LEVEL=1 KP=100U VTO=0.6 GAMMA=0, the values of ID and VL agree with our hand calculations. The results also agree for GAMMA=0.6. I DL = 6.59 ⎛W ⎞ ⎛ 2 VDSL ⎞ Kn' ⎛W ⎞ I DS = I DL | K ⎜ ⎟ ⎜VGSS − VTNS − ⎟VDSL = ⎜ ⎟ (VGSL − VTNL ) 2 ⎠ 2 ⎝ L ⎠L ⎝ L ⎠S ⎝ ⎛ 4.71⎞⎛ 2 Kn' ⎛ 1 ⎞ VO ⎞ Kn' ⎜ ⎜ ⎟⎜2.5 − 0.6 − ⎟VO = ⎟(2.5 − VO − VTNL ) 2⎠ 2 ⎝ 1.68 ⎠ ⎝ 1 ⎠⎝ ' n ( VTNL = 0.6 + 0.5 VO + 0.6 − 0.6 ) An iterative solution yields VO = 0.1061 V 6.60 ⎛W ⎞ ⎛ 2 V ⎞ K ' ⎛W ⎞ I DS = I DL | Kn' ⎜ ⎟ ⎜VH − VTNS − L ⎟VL = n ⎜ ⎟ (2.5 − VL − VTNL ) 2⎠ 2 ⎝ L ⎠L ⎝ L ⎠S ⎝ which is independent of K'n . Ratioed logic maintains VL and VH independent of K'n . So VH = 1.55V and VL = 0.20V. However, I DS = I DL ∝ Kn' : 80 μA V 2 = 64.0 μA P = 2.5V (64μA)= 0.160 mW 100 μA V 2 μA ⎛ 4.71⎞⎛ 0.2 ⎞ Checking : I DS = 80 2 ⎜ ⎟⎜1.55 − 0.6 − ⎟0.2 = 64.1μA 2 ⎠ V ⎝ 1 ⎠⎝ So, I D = 80μA 6-19 6.61 ⎛W ⎞ ⎛ 2 V ⎞ K ' ⎛W ⎞ I DS = I DL | Kn' ⎜ ⎟ ⎜VH − VTNS − L ⎟VL = n ⎜ ⎟ (2.5 − VL − VTNL ) 2⎠ 2 ⎝ L ⎠L ⎝ L ⎠S ⎝ which is independent of K'n . Ratioed logic maintains VL and VH independent of K'n . So VH = 1.55V and VL = 0.20V. However, I DS = I DL ∝ Kn' : 120 μA V 2 = 96.0 μA P = 2.5V (96μA)= 0.240 mW 100 μA V 2 0.2 ⎞ μA ⎛ 4.71⎞⎛ Checking : I DS = 120 2 ⎜ ⎟⎜1.55 − 0.6 − ⎟0.2 = 96.1μA 2 ⎠ V ⎝ 1 ⎠⎝ So, I D = 80μA 6.62 Noise Margins vs. KR 2.5 2 1.5 NMH NML 1 0.5 0 0 2 4 6 8 10 12 -0.5 KR 6.63 (a) VH = VDD – VTNL does not depend upon λ. However, VL is dependent upon λ. (b) SPICE yields VL = 0.20 V, 0.207 V, 0.217 V, and 0.232 V for λ = 0, 0.02/V, 0.05/V, and 0.1/V respectively. The current also increases: IDD = 80.1, 82.8, 86.9 and 93.3 μA, respectively. 6.64 VTNL = 0.6 + 0.5 0.20 + 0.6 − 0.6 = 0.660V ( ) VGSL − VTNL = 4 − 0.2 − 0.66 = 3.14V | VDSL = 2.5 − 0.2 = 2.30V → Triode region ⎛W ⎞ 2.3⎞ 1 μA ⎛ W ⎞ ⎛ 80μA = 100 2 ⎜ ⎟ ⎜ 4 − 0.2 − 0.66 − ⎟2.3 → ⎜ ⎟ = 2 ⎠ V ⎝ L ⎠L⎝ ⎝ L ⎠ L 5.72 ⎛W ⎞ 2.22 0.2 ⎞ μA ⎛ W ⎞ ⎛ 80μA = 100 2 ⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 V ⎝ L ⎠S ⎝ ⎝ L ⎠L 6-20 6.65 ( ) For linear operation at vo = VL : VTNL = 0.8 + 0.5 0.2 + 0.6 − 0.6 = 0.860V VGSL − VTNL ≥ VDSL : VGG − 0.20 − 0.860 ≥ 2.5 − 0.2 → VGG ≥ 3.36V ( ) We also require : VGG ≥ 2.5 + VTNL = 2.5 + 0.8 + 0.5 2.5 + 0.6 − 0.6 = 3.79V so VGG ≥ 3.79V 6.66 ( ) If VH = 3.3 V , VTNL = 0.6 + 0.5 3.3 + 0.6 − 0.6 = 1.2V 5 -1.2 = 3.8V > 3.3V so VH = 3.3 V is correct. ⎛ ⎞⎛ 2 VL ⎞ Kn' ⎛ 1 ⎞ ' 5 I DS = I DL | Kn ⎜ ⎟⎜ 3.3 − 0.6 − ⎟VL = ⎜ ⎟(3.3 − VL − VTNL ) 2⎠ 2 ⎝ 2⎠ ⎝ 1 ⎠⎝ ( VTNL = 0.6 + 0.5 VL + 0.6 − 0.6 I DS = ) An interative solution gives V = 0.1222 V , V L TNL = 0.6376 V 2 100μA ⎛ 1 ⎞ ⎜ ⎟(3.3 − 0.1222 − 0.6376) = 161 μA | P = 3.3V (161μA) = 0.532 mW 2 ⎝ 2⎠ 6.67 We require VGG ≥ VDD + VTNL so VH = VDD VTNL = VTO + γ (V SB ) + 0.6 − 0.6 = 0.6 + 0.6 ( 3.3 + 0.6 − ) 0.6 = 1.32V VGG ≥ 3.3 + 1.32 = 4.62V 6.68 We require VGG ≥ VDD + VTNL so VH = VDD VTNL = VTO + γ (V SB ) ( ) + 0.6 − 0.6 = 0.6 + 0.6 3.3 + 0.6 − 0.6 = 1.32V VGG ≥ 3.3 + 1.32 = 4.62V | Design decision - Choose VGG = 5 V I DD = 300μW = 90.9μA 3.3V ⎛W ⎞ ⎛ ⎛ W ⎞ 1.75 0.2 ⎞ For MS : 90.9μA = 100μA⎜ ⎟ ⎜3.3 − 0.6 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S ( ) For ML : VTNL = 0.6 + 0.6 0.2 + 0.6 − 0.6 = 0.672V ⎛W ⎞ ⎛ ⎛W ⎞ 3.3 − 0.2 ⎞ 1 90.9μA = 100μA⎜ ⎟ ⎜ 5 − .2 − 0.672 − ⎟(3.3 − 0.2)→ ⎜ ⎟ = 2 ⎠ ⎝ L ⎠L⎝ ⎝ L ⎠ L 8.79 6.69 We require VTNL ≤ 0 : −1+ γ ( 2.5 + 0.6 − ) 0.6 ≤ 0 → γ ≤ 1.014 6-21 6.70 (a) V H ⎛W ⎞ ⎛ 2 V ⎞ K ' ⎛W ⎞ = VDD | I DS = I DL | Kn' ⎜ ⎟ ⎜VDD − VTNS − L ⎟VL = n ⎜ ⎟ (VTNL ) 2⎠ 2 ⎝ L ⎠L ⎝ L ⎠S ⎝ For ratioed logic, both VH and VLare independent of K'n . VH = 2.5 V | VL = 0.2 V ⎛ 80 ⎞ However, I D ∝ Kn' | I DS = 80μA⎜ ⎟ = 64μA | P = 2.5V (64μA) = 0.160 mW ⎝ 100 ⎠ ⎛120 ⎞ (b) VH = 2.5 V VL = 0.2 V I DS = 80μA⎜⎝100 ⎟⎠ = 96μA | P = 2.5V (96μA)= 0.240 mW 6.71 ( ) 0.20mW = 60.1μA VTNL = −1+ 0.5 3.3 + 0.6 − 0.6 = −0.400V → VH = 3.3V 3.3V ⎛W ⎞ ⎛ ⎛W ⎞ 1.16 0.20 ⎞ | For VO = VL = 0.2V , 60.1μA = 100μA⎜ ⎟ ⎜ 3.3 − 0.6 − ⎟0.20 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S ⎛ W ⎞ 1.36 2 100μA ⎛ W ⎞ VTNL = −1+ 0.5 0.20 + 0.6 − 0.6 = −0.940V | 60.1μA = ⎜ ⎟ (−0.940) | ⎜ ⎟ = 1 2 ⎝ L ⎠L ⎝ L ⎠L I DD = ( ) 6.72 ( ) Assume VH = VDD = 3.3V | Checking : VTNL = −2 + 0.5 3.3 + 0.6 − 0.6 = −1.40 P 250μW = = 75.8μA VDD 3.3V ⎛W ⎞ ⎛ ⎛W ⎞ 1.46 0.2 ⎞ For MS in the triode region, 75.8μA = 100μA⎜ ⎟ ⎜ 3.3 − 0.6 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S VTNL < 0, so our assumption is correct. | I DD = ( ) For ML in the saturation region, VTNL = −2 + 0.5 0.2 + 0.6 − 0.6 = −1.94V and 75.8μA = 2 100μA ⎛ W ⎞ ⎜ ⎟ (0 − VTNL ) → 2 ⎝ L ⎠L ⎛W ⎞ 1 ⎜ ⎟ = ⎝ L ⎠ L 2.48 6.73 (a) No, VH does not depend upon λ. (b) As λ increases, IDD increases in ML, and VL increases. λ 0 0.02/V 0.05/V 0.1/v 6-22 IDD 78.2 μA 81.4 μA 86.0 μA 93.6 μA VL 195 mV 203 mV 214 mV 231 mV 6.74 (a) The PMOS load is still saturated, so I DD remains the same : I DD = 80μA. ⎛W ⎞ ⎛ ⎛ W ⎞ 1.80 0.25 ⎞ Also, VH = 2.5 V. 80x10-6 = 100x10-6⎜ ⎟ ⎜2.5 − 0.6 − ⎟0.25 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠n ⎝ ⎝ L ⎠n 1.80(100) V +V K 2.5 − 0.6 = 1.02 V (b) VIL = VTNS + DD2 TP KR = KS = 1.11 40 = 4.05 VIL = 0.6 + ( ) 4.052 + 4.05 K R + KR L ⎛ ⎛ KR ⎞ 4.05 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟ = 2.30V VOH = VDD − (VDD + VTP )⎜⎜1− 5.05 ⎟⎠ KR + 1 ⎠ ⎝ ⎝ V + VTP 2.5 − 0.6 = = 0.545V VIH = VTNS + 2VOL = 0.6 + 2(0.545) = 1.69V VOL = DD 3KR 3(4.05) NM H = VOH − VIH = 2.30 −1.69 = 0.610 V NM L = VIL − VOL = 1.02 − 0.545 = 0.475 V 6.75 (a) The PMOS load is still saturated, so I DD remains the same : I DD = 80μA. ⎛ 2.22 ⎞ ⎛ VL ⎞ Also, VH = 2.5 V. 80x10-6 = 100x10-6⎜ ⎟ ⎜2.5 − 0.5 − ⎟VL → VL = 0.189 V 2⎠ ⎝ 1 ⎠n ⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.6 (b) VIL = VTNS + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 5.00 VIL = 0.5 + 2 = 0.847 V 5 +5 KR + KR L ⎛ ⎛ KR ⎞ 5 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟ = 2.33V VOH = VDD − (VDD + VTP )⎜⎜1− 5 + 1 ⎟⎠ KR + 1 ⎠ ⎝ ⎝ V + VTP 2.5 − 0.6 = = 0.491V VIH = VTNS + 2VOL = 0.5 + 2(0.491) = 1.48V VOL = DD 3KR 3(5) NM H = VOH − VIH = 2.33 −1.48 = 0.849 V NM L = VIL − VOL = 0.847 − 0.491 = 0.356 V (c) The PMOS load is still saturated, so I DD remains the same : I DD = 80μA. ⎛ 2.22 ⎞ ⎛ VL ⎞ Also, VH = 2.5 V. 80x10-6 = 100x10-6⎜ ⎟ ⎜2.5 − 0.7 − ⎟VL → VL = 0.213 V 2⎠ ⎝ 1 ⎠n ⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.6 (d) VIL = VTNS + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 5.00 VIL = 0.7 + 2 = 1.05 V 5 +5 KR + KR L ⎛ ⎛ KR ⎞ 5 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟ = 2.33V VOH = VDD − (VDD + VTP )⎜⎜1− 5 + 1 ⎟⎠ KR + 1 ⎠ ⎝ ⎝ V + VTP 2.5 − 0.6 = = 0.490V VIH = VTNS + 2VOL = 0.7 + 2(0.490)= 1.68V VOL = DD 3KR 3(5) NM H = VOH − VIH = 2.33 −1.68 = 0.650 V NM L = VIL − VOL = 1.05 − 0.490 = 0.560 V 6-23 6.76 (a) The PMOS load is still saturated, so I DD remains the same : I DD = 80μA. ⎛ 2.22 ⎞ ⎛ VL ⎞ Also, VH = 2.5 V. 80x10-6 = 120x10-6⎜ ⎟ ⎜2.5 − 0.6 − ⎟VL → VL = 0.165 V 2⎠ ⎝ 1 ⎠n ⎝ V +V K 2.22 ⎛120 ⎞ 2.5 − 0.6 (b) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 6 VIL = 0.6 + 2 = 0.893V 6 +6 KR + KR L VOH ⎛ = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP = 3KR 2.5 − 0.6 3(6) ⎛ KR ⎞ 6 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟⎟ = 2.36V 6 + 1 KR + 1 ⎠ ⎝ ⎠ = 0.448V VIH = VTN + 2VOL = 0.6 + 2(0.448)= 1.50V NM H = VOH − VIH = 2.36 −1.50 = 0.860 V NM L = VIL − VOL = 0.893 − 0.448 = 0.445 V (c) The PMOS load is still saturated, so I DD remains the same : I DD = 80μA. ⎛ 2.22 ⎞ ⎛ VL ⎞ Also, VH = 2.5 V. 80x10-6 = 80x10-6 ⎜ ⎟ ⎜2.5 − 0.6 − ⎟VL → VL = 0.254 V 2⎠ ⎝ 1 ⎠n ⎝ V +V K 2.22 ⎛ 80 ⎞ 2.5 − 0.6 (d) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 4 VIL = 0.6 + 2 = 1.03V 4 +4 KR + KR L ⎛ VOH = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP 3KR = 2.5 − 0.6 3(4) ⎛ KR ⎞ 4 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟ = 2.30V 4 + 1 ⎟⎠ KR + 1 ⎠ ⎝ = 0.549V VIH = VTN + 2VOL = 0.6 + 2(0.549)= 1.70V NM H = VOH − VIH = 2.30 −1.70 = 0.600 V 6-24 NM L = VIL − VOL = 1.03 − 0.549 = 0.481 V 6.77 (a) The PMOS load is still saturated, and VH = 2.5 V. 2 40x10-6 ⎛ 1.11⎞ I DD = ⎜ ⎟ (2.5 − 0.5) → I DD = 88.8 μA 2 ⎝ 1 ⎠n ⎛ 2.22 ⎞ ⎛ VL ⎞ For MS : 88.8x10-6 = 100x10-6 ⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟VL → VL = 0.224 V 2⎠ ⎝ 1 ⎠n⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.5 (b) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 5 VIL = 0.6 + 2 = 0.965V 5 +5 KR + KR L ⎛ VOH = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP = 3KR 2.5 − 0.5 3(5) ⎛ KR ⎞ 5 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.5)⎜⎜1− ⎟⎟ = 2.33V 5 + 1 KR + 1 ⎠ ⎝ ⎠ = 0.516V VIH = VTN + 2VOL = 0.6 + 2(0.516) = 1.63V NM H = VOH − VIH = 2.33 −1.63 = 0.700 V NM L = VIL − VOL = 0.965 − 0.516 = 0.449 V (c) The PMOS load is still saturated, and VH = 2.5 V. 2 40x10-6 ⎛ 1.11⎞ I DD = ⎜ ⎟ (2.5 − 0.7) → I DD = 71.9 μA 2 ⎝ 1 ⎠n ⎛ 2.22 ⎞ ⎛ VL ⎞ For the NMOS device : 71.9x10-6 = 100x10-6 ⎜ ⎟ ⎜2.5 − 0.6 − ⎟VL → VL = 0.179 V 2⎠ ⎝ 1 ⎠n⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.7 (d) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 40 ⎟⎠ = 5 VIL = 0.6 + 2 = 0.929V 5 +5 KR + KR L ⎛ VOH = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP 3KR = 2.5 − 0.7 3(5) ⎛ KR ⎞ 5 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.7)⎜⎜1− ⎟ = 2.34V 5 + 1 ⎟⎠ KR + 1 ⎠ ⎝ = 0.465V VIH = VTN + 2VOL = 0.6 + 2(0.465) = 1.53V NM H = VOH − VIH = 2.34 −1.53 = 0.810 V NM L = VIL − VOL = 0.929 − 0.465 = 0.464 V 6-25 6.78 (a) The PMOS load is still saturated, and VH = 2.5 V. 2 50x10-6 ⎛ 1.11⎞ I DD = ⎜ ⎟ (2.5 − 0.6) → I DD = 100 μA 2 ⎝ 1 ⎠n ⎛ 2.22 ⎞ ⎛ VL ⎞ For MS : 100x10-6 = 100x10-6 ⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟VL → VL = 0.254 V 2⎠ ⎝ 1 ⎠n⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.6 (b) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 50 ⎟⎠ = 4 VIL = 0.6 + 2 = 1.03V 4 +4 KR + KR L ⎛ VOH = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP = 3KR 2.5 − 0.6 3(4) ⎛ KR ⎞ 4 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟⎟ = 2.30V 4 + 1 KR + 1 ⎠ ⎝ ⎠ = 0.549V VIH = VTN + 2VOL = 0.6 + 2(0.549)= 1.70V NM H = VOH − VIH = 2.30 −1.70 = 0.600 V NM L = VIL − VOL = 1.03 − 0.549 = 0.481 V (c) The PMOS load is still saturated, and VH = 2.5 V. 2 30x10-6 ⎛ 1.11⎞ I DD = ⎜ ⎟ (2.5 − 0.6) → I DD = 60.0 μA 2 ⎝ 1 ⎠n ⎛ 2.22 ⎞ ⎛ VL ⎞ For the NMOS device : 60x10-6 = 100x10-6 ⎜ ⎟ ⎜2.5 − 0.6 − ⎟VL → VL = 0.148 V 2⎠ ⎝ 1 ⎠n⎝ V +V K 2.22 ⎛100 ⎞ 2.5 − 0.6 = 0.866V (d) VIL = VTN + DD2 TP KR = KS = 1.11 ⎜⎝ 30 ⎟⎠ = 6.67 VIL = 0.6 + 2 6.67 + 6.67 KR + KR L ⎛ VOH = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP 3KR = 2.5 − 0.6 3(6.67) ⎛ KR ⎞ 6.67 ⎞ ⎟⎟ = 2.5 − (2.5 − 0.6)⎜⎜1− ⎟ = 2.37V 6.67 + 1 ⎟⎠ KR + 1 ⎠ ⎝ = 0.425V VIH = VTN + 2VOL = 0.6 + 2(0.425)= 1.45V NM H = VOH − VIH = 2.37 −1.45 = 0.920 V 6.79 (a) I DD = NM L = VIL − VOL = 0.866 − 0.425 = 0.441 V P 100μW = = 55.6μA VDD 1.8V For the saturated PMOS load : 55.6x10-6 = ⎛W ⎞ 2 25x10-6 ⎛W ⎞ 2.63 ⎜ ⎟ (1.8 − 0.5) → ⎜ ⎟ = 2 ⎝ L ⎠p 1 ⎝ L ⎠p ⎛W ⎞ ⎛ ⎛W ⎞ 3.86 0.2 ⎞ For the linear NMOS switch : 55.6x10-6 = 60x10-6 ⎜ ⎟ ⎜1.8 − 0.5 − ⎟0.2 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ n⎝ ⎝ L ⎠n 6-26 (b) V IL VOH = VTN + VDD + VTP K + KR ⎛ = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP 2 R = 3KR 1.8 − 0.5 3(3.52) KR = KS 3.86 ⎛ 60 ⎞ = ⎜ ⎟ = 3.52 KL 2.63 ⎝ 25 ⎠ (a) I D = 1.8 − 0.5 3.522 + 3.52 = 0.826V ⎛ KR ⎞ 3.52 ⎞ ⎟⎟ = 1.8 − (1.8 − 0.5)⎜⎜1− ⎟ = 1.65V KR + 1 ⎠ 3.52 + 1 ⎟⎠ ⎝ = 0.400V VIH = VTN + 2VOL = 0.5 + 2(0.400) = 1.30V NM H = VOH − VIH = 1.60 −1.30 = 0.300 V 6.80 VIL = 0.5 + NM L = VIL − VOL = 0.826 − 0.400 = 0.426 V P 200μW = = 66.7μA VDD 3V For the saturated PMOS load : 66.7x10-6 = ⎛W ⎞ 2 25x10-6 ⎛W ⎞ 0.926 1 = ⎜ ⎟ (3 − 0.6) → ⎜ ⎟ = 2 ⎝ L ⎠p 1 1.08 ⎝ L ⎠p ⎛W ⎞ ⎛ ⎛W ⎞ 1.65 0.3 ⎞ For the linear NMOS switch : 66.7x10-6 = 60x10-6 ⎜ ⎟ ⎜ 3 − 0.6 − ⎟0.3 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ n⎝ ⎝ L ⎠n ⎛ 60 ⎞ V +V K 3 − 0.6 = 1.11V (b) VIL = VTN + DD2 TP KR = KS = 1.65(1.08)⎜⎝ 25 ⎟⎠ = 4.28 VIL = 0.6 + 4.282 + 4.28 KR + KR L VOH ⎛ = VDD − (VDD + VTP )⎜⎜1− ⎝ VOL = VDD + VTP 3KR = 3 − 0.6 3(4.28) ⎛ KR ⎞ 4.28 ⎞ ⎟⎟ = 3 − (3 − 0.6)⎜⎜1− ⎟⎟ = 2.76V 4.28 + 1 KR + 1 ⎠ ⎝ ⎠ = 0.670V NM H = VOH − VIH = 2.76 −1.94 = 0.821 V VIH = VTN + 2VOL = 0.6 + 2(0.670)= 1.94V NM L = VIL − VOL = 1.11− 0.670 = 0.440 V 6.81 With A = 1 = B, the circuit is equivalent to a single 4.44/1 switching device. ⎛ 4.44 ⎞⎛ 2 VL ⎞ 100μA ⎛1.81⎞ 100μA⎜ ⎟⎜ 2.5 − 0.6 − ⎟VL = ⎜ ⎟(VTNL ) | VTNL = −1+ 0.5 VL + 0.6 − 0.6 2⎠ 2 ⎝ 1 ⎠ ⎝ 1 ⎠⎝ 2 100μA ⎛ 1.81⎞ Solving iteratively → VL = 0.1033V | VTNL = −0.968V (b) I DD = ⎜ ⎟(0.968) = 84.8 μA 2 ⎝ 1 ⎠ ( ) 6-27 6.82 ⎛W ⎞ ⎛ ⎛W ⎞ 0.1⎞ 4.32 80μA = 100μA⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟0.1 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A⎝ ⎝ L ⎠A ( ) VTNB = 0.6 + 0.5 0.1+ 0.6 − 0.6 = 0.631 ⎛W ⎞ ⎛ ⎛W ⎞ 0.1⎞ 4.65 80μA = 100μA⎜ ⎟ ⎜ 2.5 − 0.1− 0.631− ⎟0.1 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠A 6.83 We require Ron R R + on = on and the total area AT ∝ (WL)A + (WL)B ⎛W ⎞ ⎛W ⎞ K ⎜ ⎟ ⎜ ⎟ ⎝ L ⎠A ⎝ L ⎠B 1 1 1 KW B KW B W B2 + = → WA = → AT ∝ + WB = WB − K WB − K WB − K WA WB K d ⎛ W B2 ⎞ W B2 − 2KW B Finding the minimum : = 0 → W B = 2K & WA = 2K. ⎜ ⎟= dWB ⎝ W B − K ⎠ (W B − K )2 Setting L = 1, 6.84 +2.5 V ML 1.81 1 Y M MA A 6-28 2.22 1 B 2.22 1 MD MC B C 2.22 1 D 2.22 1 6.85 +2.5 V ML 1.81 1 Y D MD 8.88 1 C MC 8.88 1 B MB 8.88 1 A MA 8.88 1 6.86 +2.5 V ML 1.11 1 Y A 2.22 1 MC MB MA B 2.22 1 C 2.22 1 (a ) With A = B = C = 1, the circuit is equivalent to a single 6.66/1 switching device. ⎛ 6.66 ⎞⎛ 2 40μA ⎛1.81⎞ VL ⎞ 100μA⎜ ⎟⎜ 2.5 − 0.6 − ⎟VL = ⎜ ⎟(0.6) → VL = 0.1033V 2⎠ 2 ⎝ 1 ⎠ ⎝ 1 ⎠⎝ 2 40μA ⎛ 1.81⎞ (b) I DD = 2 ⎜⎝ 1 ⎟⎠(0.6) = 13.0 μA 6-29 6.87 +2.5 V (a) 1.11 1 ML Y C MC 6.66 1 B MB 6.66 1 A MA 6.66 1 (b) The PMOS device remains saturated with I DD = 80μA. ⎛ 6.66 ⎞⎛ VDSA ⎞ For MA : 80μA = 100μA⎜ ⎟⎜ 2.5 − 0.6 − ⎟VDSA → VDSA = 0.0643V 2 ⎠ ⎝ 1 ⎠⎝ ( ) For MB :VTNB = 0.6 + 0.5 0.0643 + 0.6 − 0.6 = 0.620 ⎛ 6.66 ⎞⎛ VDSB ⎞ 80μA = 100μA⎜ ⎟⎜ 2.5 − .0643 − 0.620 − ⎟VDSB → VDSB = 0.0674V 2 ⎠ ⎝ 1 ⎠⎝ ( ) For MC :VTNC = 0.6 + 0.5 0.0643 + 0.674 + 0.6 − 0.6 = 0.640 ⎛ 6.66 ⎞⎛ VDSC ⎞ 80μA = 100μA⎜ ⎟⎜ 2.5 − .0674 − .0643 − 0.640 − ⎟VDSC → VDSC = 0.0709V 2 ⎠ ⎝ 1 ⎠⎝ VL = VDSA + VDSB + VDSC = 0.203 V (c) Assume equal values of 0.2 = 0.0667V 3 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.43 For MA : 80μA = 100μA⎜ ⎟ ⎜ 2.5 − 0.6 − ⎟0.0667 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A⎝ ⎝ L ⎠A ( VDS = ) For MB :VTNB = 0.6 + 0.5 0.0667 + 0.6 − 0.6 = 0.621 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.74 80μA = 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621− ⎟0.0667 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B ( ) For MC :VTNC = 0.6 + 0.5 0.1334 + 0.6 − 0.6 = 0.641 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 7.09 80μA = 100μA⎜ ⎟ ⎜ 2.5 − 0.1334 − 0.641− ⎟0.0667 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B 6-30 6.88 VDD 1/1.7 vO 2/14.7/1 A 4.7/1 2/1 B Ground 6.89 VDD 1/1.7 vO C A 4.7/1 2/1 2/14.7/1 Ground 6.90 4.7/1 2/1 B ⎛ W ⎞ 1.81 Y = (A + B)(C + D)(E + F ) | ⎜ ⎟ = 1 ⎝ L ⎠L ⎛ W⎞ ⎛ 2.22 ⎞ 6.66 | ⎜ ⎟ =3⎜ ⎟= 1 ⎝ L ⎠ A−F ⎝ 1 ⎠ 6.91 (a) The only change to the schematic is to connect the gate of load transistor ML to its drain instead of its source. (b) There is no change to the logic function Y = (A + B)(C + D)(E + F ) ⎛ W⎞ ⎛ W⎞ ⎛ 4.71⎞ 14.1 1 | ⎜ ⎟ =3⎜ ⎟= (c) ⎜ ⎟ = 1 ⎝ L ⎠ L 1.68 ⎝ L ⎠ ABCDEF ⎝ 1 ⎠ 6-31 6.92 ⎛ W ⎞ 1.11 Y = (A + B)(C + D)E | ⎜ ⎟ = 1 ⎝ L ⎠L ⎛ W⎞ ⎛ 2.22 ⎞ 6.66 | ⎜ ⎟ =3⎜ ⎟= 1 ⎝ L ⎠ A− E ⎝ 1 ⎠ 6.93 (a) In the new circuit schematic, the PMOS transistor is replaced with a saturated NMOS load device as in Fig. 6.29(b). (b) The logic function is unchanged: Y = (A + B)(C + D)E ⎛ W⎞ ⎛ W⎞ ⎛ 4.71⎞ 14.1 1 (c) ⎜ ⎟ = | ⎜ ⎟ =3⎜ ⎟= 1 ⎝ L ⎠ L 1.68 ⎝ L ⎠ ABCDE ⎝ 1 ⎠ 6.94 (a) Y = ACE + ACDF + BF + BDE (b) ⎛ W⎞ 1.11 3.33 = | ACDF path contains 4 devices ⎜ ⎟ =3 1 1 ⎝ L ⎠L ⎡ ⎛ 2.22 ⎞⎤ 26.6 ⎛ W⎞ ⎛ W⎞ 1 1 1 1 17.8 = 3 | + + = →⎜ ⎟ = ⎢4 ⎜ ⎜ ⎟ ⎟⎥ = ⎛ W⎞ ⎛ 26.6 ⎞ ⎛ W ⎞ 2.22 1 1 ⎝ L ⎠ A, C , D , F ⎝ L ⎠B , E ⎣ ⎝ 1 ⎠⎦ 3 ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ 1 ⎝ L ⎠B ⎝ 1 ⎠ ⎝ L ⎠E 6.95 (a) In the new circuit schematic, the PMOS transistor is replaced with a saturated NMOS load device as in Fig. 6.29(b). (b) There is no change to the logic function Y = ACDF + ACE + BDE + BF ⎛ W⎞ ⎛ W⎞ ⎛ 4.71⎞ 18.8 1 (c) ⎜⎝ L ⎟⎠ = 1.68 | ⎜⎝ L ⎟⎠ = 4 ⎜⎝ 1 ⎟⎠ = 1 L ACDF RoB + RonD + RonE setting RoB = RonE : ⎛ W ⎞ 12.6 1 1 1 2 1 1 + + = + = →⎜ ⎟ = ⎛ W⎞ ⎛ W⎞ 18.8 ⎛ W ⎞ 18.8 4.71 ⎝ L ⎠ B 1 ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ L ⎠B ⎝ L ⎠E ⎝ L ⎠B Checking : RoB + RonF = 6-32 1 1 1 1 + = ≤ so path BF is ok. 18.8 12.6 7.42 4.71 6.96 +2.5 V Y D E B C A ⎛W ⎞ 1.81 ⎜ ⎟ = 1 ⎝ L ⎠L DCA and ECA paths contain three devices ⎛W ⎞ ⎛ 2.22 ⎞ 6.66 = 3⎜ ⎜ ⎟ ⎟= 1 ⎝ L ⎠ A,C , D, E ⎝ 1 ⎠ 1 1 1 + = ⎛W ⎞ ⎛W ⎞ ⎛ 2.22 ⎞ ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ L ⎠ A ⎝ L ⎠B ⎝ 1 ⎠ ⎛W ⎞ 1 1 1 3.33 + = →⎜ ⎟ = ⎛ 6.66 ⎞ ⎛W ⎞ ⎛ 2.22 ⎞ ⎝ L ⎠ 1 B ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ 1 ⎠ A ⎝ 1 ⎠B ⎝ 1 ⎠ 6-33 6.97 +2.5 V C E B D A ⎛W ⎞ 1 ⎛1.11⎞ 1 ⎜ ⎟ = ⎜ ⎟= ⎝ L ⎠ L 2 ⎝ 1 ⎠ 1.80 CBA and EDA paths contain three devices ⎛W ⎞ 1 ⎛ 2.22 ⎞ 3.33 = (3)⎜ ⎜ ⎟ ⎟= 1 ⎝ L ⎠ A− E 2 ⎝ 1 ⎠ 6-34 6.98 +2.5 V Y C E B D A ⎛W ⎞ 1 ⎜ ⎟ = ⎝ L ⎠ L 1.68 CBA and EDA paths contain three devices ⎛W ⎞ ⎛ 4.71⎞ 14.1 = 3⎜ ⎜ ⎟ ⎟= 1 ⎝ L ⎠ A− E ⎝ 1 ⎠ 6-35 6.99 +2.5 V ML Y E D B C A ⎛W ⎞ 1.11 ⎜ ⎟ = 1 ⎝ L ⎠L ⎛W ⎞ 2.22 ⎜ ⎟ = 1 ⎝ L ⎠E DCA path contains three devices ⎛W ⎞ ⎛ 2.22 ⎞ 6.66 = 3⎜ ⎜ ⎟ ⎟= 1 ⎝ L ⎠ A,C , D ⎝ 1 ⎠ ⎛W ⎞ 1 1 1 3.33 + = →⎜ ⎟ = ⎛ 6.66 ⎞ ⎛W ⎞ ⎛ 2.22 ⎞ ⎝ L ⎠ 1 B ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ 1 ⎠ A ⎝ 1 ⎠B ⎝ 1 ⎠ 6.100 [ ] Y = A(B + D)(C + E )+ (C + E )G + F = (C + E ) A(B + D)+ G + F ⎛ W⎞ 1.81 3.62 = | ⎜ ⎟ =2 1 1 ⎝ L ⎠L ⎛ W⎞ ⎛ 2.22 ⎞ 4.44 ⎜ ⎟ = 2⎜ ⎟= 1 ⎝ L ⎠F ⎝ 1 ⎠ 6-36 ⎡ ⎛ 2.22 ⎞⎤ 13.3 ⎛ W⎞ = 2 ⎢3⎜ ⎜ ⎟ ⎟⎥ = 1 ⎝ L ⎠ A− E ⎣ ⎝ 1 ⎠⎦ | ⎛ W⎞ 1 1 1 6.67 + = →⎜ ⎟ = ⎛ W⎞ ⎛13.3 ⎞ 2.22 ⎝ L ⎠G 1 ⎜ ⎟ ⎜ ⎟ 2 1 ⎝ L ⎠G ⎝ 1 ⎠ 6.101 (a) +2.5 V ML Y E D B C A ⎛W ⎞ 1.81 ⎜ ⎟ = 1 ⎝ L ⎠L ⎛W ⎞ 2.22 ⎜ ⎟ = 1 ⎝ L ⎠E DCA path contains three devices ⎛W ⎞ ⎛ 2.22 ⎞ 6.66 = 3⎜ ⎜ ⎟ ⎟= 1 ⎝ L ⎠ A,C , D ⎝ 1 ⎠ ⎛W ⎞ 1 1 1 3.33 + = →⎜ ⎟ = ⎛ 6.66 ⎞ ⎛W ⎞ ⎛ 2.22 ⎞ ⎝ L ⎠ 1 B ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ 1 ⎠ A ⎝ 1 ⎠B ⎝ 1 ⎠ (b) Device E remains the same. 0.20 VL 0.20 V = = 0.0667V | B : VDS = 2 L = 2 = 0.133V 3 3 3 3 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.43 100μA⎜ ⎟ ⎜ 2.5 − .6 − ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A⎝ ⎝ L ⎠A A, C , D : VDS = ( ) VTNB = VTNC = 0.6 + 0.5 0.0667 + 0.6 − 0.6 = 0.621V ⎛W ⎞ ⎛ ⎛W ⎞ 0.133⎞ 3.45 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621 − ⎟0.133 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.74 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621 − ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠C ⎝ ⎝ L ⎠C ( ) VTND = 0.6 + 0.5 0.133 + 0.6 − 0.6 = 0.641V ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 7.09 100μA⎜ ⎟ ⎜ 2.5 − 0.133 − 0.641 − ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠D ⎝ ⎝ L ⎠D 6-37 6.102 ⎛W ⎞ 2.22 Device A remains the same. ⎜ ⎟ = 1 ⎝ L ⎠A VL 0.20 = = 0.100V 2 2 ⎛W ⎞ ⎛ ⎛W ⎞ 0.100 ⎞ 4.32 100μA⎜ ⎟ ⎜2.5 − 0.6 − ⎟0.100 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠C, D ⎝ ⎝ L ⎠C , D B,C, D : VDS = ( ) VTNB = 0.6 + 0.5 0.100 + 0.6 − 0.6 = 0.631V ⎛W ⎞ ⎛ ⎛W ⎞ 0.100 ⎞ 4.65 100μA⎜ ⎟ ⎜ 2.5 − 0.100 − 0.631− ⎟0.100 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B 6.103 The load device remains the same. VL 0.20 V 0.20 = = 0.0667V | A : VDS = 2 L = 2 = 0.133V 3 3 3 3 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.43 100μA⎜ ⎟ ⎜ 2.5 − .6 − ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B B,C, D : VDS = ( ) VTNA = VTND = 0.6 + 0.5 0.0667 + 0.6 − 0.6 = 0.621V ⎛W ⎞ ⎛ ⎛W ⎞ 0.133⎞ 3.45 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621− ⎟0.133 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A⎝ ⎝ L ⎠A ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.74 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621− ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠D ⎝ ⎝ L ⎠D ( ) VTNC = 0.6 + 0.5 0.133 + 0.6 − 0.6 = 0.641V ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 7.09 100μA⎜ ⎟ ⎜ 2.5 − 0.133 − 0.641− ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠C ⎝ ⎝ L ⎠C 6-38 6.104 The load device remains the same. VL 0.20 V 0.20 = = 0.10V | C, D : VDS = L = = 0.050V 2 4 2 4 ⎛W ⎞ ⎛ ⎛W ⎞ 0.10 ⎞ 4.32 100μA⎜ ⎟ ⎜ 2.5 − .6 − ⎟0.10 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B ⎝ ⎝ L ⎠B A, B : VDS = ( ) VTNA = VTND = 0.6 + 0.5 0.1+ 0.6 − 0.6 = 0.631V ⎛W ⎞ ⎛ ⎛W ⎞ 0.10 ⎞ 4.65 100μA⎜ ⎟ ⎜ 2.5 − 0.10 − 0.631− ⎟0.10 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A⎝ ⎝ L ⎠A ⎛W ⎞ ⎛ ⎛W ⎞ 0.05⎞ 9.17 100μA⎜ ⎟ ⎜ 2.5 − 0.10 − 0.631− ⎟0.05 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠D ⎝ ⎝ L ⎠D ( ) VTNC = 0.6 + 0.5 0.15 + 0.6 − 0.6 = 0.646V ⎛W ⎞ ⎛ ⎛W ⎞ 0.05⎞ 9.53 100μA⎜ ⎟ ⎜ 2.5 − 0.15 − 0.646 − ⎟0.05 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠C ⎝ ⎝ L ⎠C 6.105 Device E and the load device remain the same. In the worst case, for paths BCD or ADE VL 0.20 = = 0.0667V 3 3 ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.43 100μA⎜ ⎟ ⎜2.5 − .6 − ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠B , E ⎝ ⎝ L ⎠B , E A, B,C, D, E : VDS = ( ) VTND = 0.6 + 0.5 0.0667 + 0.6 − 0.6 = 0.621V ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 6.74 100μA⎜ ⎟ ⎜ 2.5 − 0.0667 − 0.621− ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠D ⎝ ⎝ L ⎠D ( ) VTNA = VTNC = 0.6 + 0.5 0.133 + 0.6 − 0.6 = 0.641V ⎛W ⎞ ⎛ ⎛W ⎞ 0.0667 ⎞ 7.09 100μA⎜ ⎟ ⎜2.5 − 0.133 − 0.641− ⎟0.0667 = 80μA → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠ A, C ⎝ ⎝ L ⎠ A,C 6-39 6.106 A 0 (a) 0 1 1 B Y 0 1 1 0 0 1 (b) Y = AB + AB = A ⊕ B 0 1 (c) Assuming equal voltage drops (0.10V) across MP and MS : MP must carry one unit of load current with one - half the drain - source ⎛ W⎞ 4.44 voltage (VDS = 0.10V ) of the switching transistor in Fig.6.29(d). → ⎜ ⎟ = 1 ⎝ L ⎠P MS must carry two units of load current with one - half the drain - source ⎛ W⎞ 8.88 voltage (VDS = 0.10V ) of the switching transistor in Fig.6.29(d). → ⎜ ⎟ = 1 ⎝ L ⎠S (d) MS will not change. MP will need to be somewhat larger. (e) Coincidence gate (Exclusive NOR) 6.107 Original design 0.20 mW - 1 mW requires 5 times larger current. ⎛ W⎞ 28.8kΩ 2.22 11.1 (a) R = = 5.76kΩ ⎜ ⎟ = 5 = 5 1 1 ⎝ L ⎠S ⎛ W⎞ 1 2.98 (b) ⎜ ⎟ = 5 = 1.68 1 ⎝ L ⎠L ⎛ W⎞ 1 1 (c) ⎜ ⎟ = 5 = 5.72 1.14 ⎝ L ⎠L ⎛ W⎞ 1.81 9.05 (d) ⎜ ⎟ = 5 = 1 1 ⎝ L ⎠L ⎛ W⎞ 4.71 23.6 = ⎜ ⎟ =5 1 1 ⎝ L ⎠S ⎛ W⎞ 2.22 11.1 = ⎜ ⎟ =5 1 1 ⎝ L ⎠S ⎛ W⎞ 2.22 11.1 = ⎜ ⎟ =5 1 1 ⎝ L ⎠S ⎛ W⎞ 1.11 5.55 ⎛ W ⎞ 2.22 11.1 (e) ⎜ ⎟ = 5 = = ⎜ ⎟ =5 1 1 1 1 ⎝ L ⎠L ⎝ L ⎠S 6.108 ⎛ W⎞ 1.81 7.24 = | ⎜ ⎟ =4 1 1 ⎝ L ⎠L ⎛ W⎞ ⎛ 2.22 ⎞ 8.88 ⎜ ⎟ = 4⎜ ⎟= 1 ⎝ L ⎠F ⎝ 1 ⎠ 6-40 ⎡ ⎛ 2.22 ⎞⎤ 26.6 ⎛ W⎞ = 4 ⎢3 ⎜ ⎜ ⎟ ⎟⎥ = 1 ⎝ L ⎠ A− E ⎣ ⎝ 1 ⎠⎦ ⎛ W ⎞ 13.3 1 1 1 | + = →⎜ ⎟ = ⎛ W⎞ ⎛ 26.6 ⎞ 2.22 1 ⎝ L ⎠G ⎜ ⎟ ⎜ ⎟ 4 1 ⎝ L ⎠G ⎝ 1 ⎠ 6.109 ⎛ W ⎞ 1 ⎛1.81⎞ 1 ⎜ ⎟ = ⎜ ⎟= ⎝ L ⎠ L 4 ⎝ 1 ⎠ 2.21 ⎛ W⎞ 1 ⎡ ⎛ 2.22 ⎞⎤ 1.67 | ⎜ ⎟ = ⎢3 ⎜ ⎟⎥ = 1 ⎝ L ⎠ A− F 4 ⎣ ⎝ 1 ⎠⎦ 6.110 ⎛ W⎞ ⎛ 1.81⎞ 5.43 ⎛ W⎞ ⎛ 6.66 ⎞ 20.0 ⎛ W⎞ ⎛ 3.33 ⎞ 9.99 (a) ⎜⎝ L ⎟⎠ = 3⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 3⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 3⎜⎝ 1 ⎟⎠ = 1 L BCD A ⎛ W ⎞ 1 ⎛1.81⎞ ⎛ W⎞ ⎛ W⎞ 1 1 1 ⎛ 6.66 ⎞ 1.33 1 ⎛ 3.33 ⎞ (b) ⎜⎝ L ⎟⎠ = 5 ⎜⎝ 1 ⎟⎠ = 2.76 | ⎜⎝ L ⎟⎠ = 5 ⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 5 ⎜⎝ 1 ⎟⎠ = 1.50 L BCD A 6.111 ⎛ W⎞ ⎛ W⎞ ⎛ W⎞ ⎛ 1 ⎞ 1 1 1 1 ⎛1.81⎞ 1 ⎛ 4.44 ⎞ (a) ⎜⎝ L ⎟⎠ = 10 ⎜⎝ 1 ⎟⎠ = 5.53 | ⎜⎝ L ⎟⎠ = 10 ⎜⎝ 1 ⎟⎠ = 2.25 | ⎜⎝ L ⎟⎠ = 2⎜⎝ 2.25⎟⎠ = 1.13 L AB CD ⎞ ⎛ W ⎞ 2.5 ⎛1.81⎞ 4.53 ⎛ W⎞ ⎛ ⎛ ⎛ 11.1⎞ 22.2 2.5 4.44 11.1 W⎞ (b) ⎜⎝ L ⎟⎠ = 1 ⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 1 ⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 2⎜⎝ 1 ⎟⎠ = 1 L AB CD 6.112 ⎛ W⎞ ⎛ 1.11⎞ 4.44 ⎛ W⎞ ⎛ 6.66 ⎞ 26.6 (a) ⎜⎝ L ⎟⎠ = 4⎜⎝ 1 ⎟⎠ = 1 | ⎜⎝ L ⎟⎠ = 4⎜⎝ 1 ⎟⎠ = 1 L ABCDE ⎞ ⎛ W ⎞ 1 ⎛1.11⎞ ⎛ 1 W 1 ⎛ 6.66 ⎞ 2.22 (b) ⎜⎝ L ⎟⎠ = 3 ⎜⎝ 1 ⎟⎠ = 2.70 | ⎜⎝ L ⎟⎠ = 3 ⎜⎝ 1 ⎟⎠ = 1 L ABCDE 6.113 ⎛W ⎞ 2 2 1 1 ε ⎛W ⎞ (a) I D = μnCox" ⎜ ⎟(VGS − VTN ) = μn ox ⎜ ⎟(VGS − VTN ) 2 2 Tox ⎝ L ⎠ ⎝ L⎠ ⎛W ⎞ 2 1 ε ⎜ ⎟ I* I D* = μn ox ⎜ 2 ⎟(VGS − VTN ) = 2I D | D = 2 ID 2 Tox ⎜ L ⎟ 2 ⎝2⎠ (b) PD* = V (2I )= 2VI = 2PD - Power dissipation has increased by a factor of two. 6-41 6.114 dv | Assume the transition occurs in ΔT seconds generating dt 2.5V a current pulse with constant amplitude I = 10x10−12 F . ΔT 2.5x10−11 ΔT Then I avg = = 500μA and P = 64(2.5V )I avg = 64(2.5)(0.50mA)= 80 mW 50ns ΔT ⎛ 3.3 ⎞2 2 (b) P ∝V so P = 80mW ⎜ ⎟ = 139 mW ⎝ 2.5 ⎠ For each line : i = C 6.115 C C τ PHL ∝ and τ PLH ∝ KS KL C C"oxWL L2 | For either case, τ PHL ∝ = = μn KS " W μnCox L 6.116 τP = PDP 100 fJ 10−13 J = = −4 = 1 ns PD 100μW 10 W 6.117 2.5 + 0.20 = 1.35V 2 = 0.25 + 0.23 = 0.48V VH = 2.5V | VL = 0.20V | V50% = V90% = 2.5 − 0.23 = 2.27V | V10% (a) vI : t r = 22.5 −1.5 = 21 ns | vO : t r = 81− 58 = 23 ns vI : t f = 62 − 55 = 7 ns | vO : t r = 12.5 − 6 = 6.5 ns (b) τ PHL = 2.5 ns | τ PLH = 7 ns (c) τ P = 6.118 (a) T = 301(τ PHL + τ PLH ) = 602 2.5 + 7 = 4.8 ns 2 (τ PHL + τ PLH ) = 602τ P = 602(0.1ns) = 60.2 ns 2 (b) An even number of inverters has a potential steady state and may not oscillate. 6-42 6.119 t r = 2.2RC = 2.2(28.8kΩ)(0.5 pF )= 31.7 ns t f ≅ 3.7RonS C = 3.7(0.5 pF ) 3.7C = = 4.39 ns Kn (VGS − VTN ) 2.22 10−4 (2.5 − 0.6) ( ) τ PLH = 0.69RC = 0.69(28.8kΩ)(0.5 pF )= 9.94 ns τ PHL ≅ 1.2RonS C = 1.2(0.5 pF ) 1.2C = = 1.78 ns Kn (VGS − VTN ) 2.22 10−4 (2.5 − 0.6) ( ) τP = 9.94 + 1.78 = 5.86 ns 2 τP = 9.94 + 1.00 = 5.47 ns 2 6.120 t r = 2.2RC = 2.2(28.8kΩ)(0.5 pF )= 31.7 ns t f ≅ 3.7RonS C = 3.7(0.5 pF ) 3.7C = = 3.09 ns Kn (VGS − VTN ) 2.22 10−4 (3.3 − 0.6) ( ) τ PLH = 0.69RC = 0.69(28.8kΩ)(0.5 pF )= 9.94 ns τ PHL ≅ 1.2RonS C = 1.2(0.5 pF ) 1.2C = = 1.00 ns Kn (VGS − VTN ) 2.22 10−4 (3.3 − 0.6) 6.121 Resistive Load : τ P = ( ) τ PLH + τ PHL 2 VH = 2.5V τ PLH = 0.69RC and τ PHL = 1.2RonS C for RonS = VL = 0.20V VTNS = 0.6V C C 0.526C = = KS KS (VH − VTNS ) KS (2.5 − 0.6) ⎛ V ⎞ 2.5 − 0.20 2.5 − VL = KS ⎜VGS − VTN − L ⎟VL → KS R = = 6.39 ⎛ R 2⎠ 0.20 ⎞ ⎝ ⎜2.5 − 0.6 − ⎟0.20 2 ⎠ ⎝ ⎡ ⎛ 6.39 ⎞ 0.526⎤ ⎛W ⎞ 1 987 16.5 μA 2.5ns = (1pF )⎢0.69⎜ = and R = 6.47 kΩ ⎥ → KS = 987 2 | ⎜ ⎟ = ⎟+ KS ⎦ 2 1 V ⎝ L ⎠ S 60 ⎝ KS ⎠ ⎣ I DDL = (2.5 − 0.20)V = 356μA 6.47kΩ | P= 2.5(356μA) 2 = 0.444 mW 6.122 Resistive load inverter – λ has very little effect on the results: λ = 0 : t r = 3.8ns t f = 1.3ns τ PLH = 10.0ns τ PHL = 1.6ns λ = 0.04/V : t r = 31.6ns t f = 3.6ns τ PLH = 9.9ns τ PHL = 1.5ns 6.123 6-43 Ignore body effect for simplicity. Equate drain currents to find VL : ⎛ 2 V ⎞ 1 Kn' 2.5 − VL − 0.6) = 4Kn' ⎜2.5 − 0.6 − 0.6 − L ⎟VL → VL = 0.156V ( 2 2 2⎠ ⎝ 1 1 RonL = = = 19.1kΩ KL (VGS − VTN ) 0.5 60x10−6 (2.5 − 0.156 − 0.6) ( RonS = 1 = ) ( ) 1 KS (VGS − VTN ) 4 60x10−6 (2.5 − 0.6 − 0.6) = 3.21kΩ t r ≅ 11.9RonLC = 11.9(0.5 pF )(19.1kΩ) = 114 ns t f ≅ 3.7RonS C = 3.7(0.5 pF )(3.21kΩ) = 5.94 ns τ PLH ≅ 3.0RonLC = 3.0(0.5 pF )(19.1kΩ)= 28.7 ns τ PHL ≅ 1.2RonS C = 1.2(0.5 pF )(3.21kΩ)= 1.93 ns τP = 28.7 + 1.93 = 15.3 ns 2 6.124 Ignore body effect for simplicity. Equate drain currents to find VL : VTN = 0.6 → VH = 3.3 − 0.6 = 2.7V ( ) −6 ⎛ 2 4 VL ⎞ 1 60x10 −6 60x10 ⎜2.7 − 0.6 − ⎟VL = 3.3 − VL − 0.6) ( 2⎠ 2 1 2 ⎝ ( ) 9VL2 − 39.0VL + 7.29 = 0 → VL = 0.196V RonL = RonS = ( 0.5 60x10 ( 4 60x10 −6 ) 1 (3.3 − 0.196 − 0.6) 1 −6 )(2.7 − 0.6) = 13.3kΩ = 1.98kΩ t r = 11.9RonLC = 11.9(13.3kΩ)(0.3 pF )= 47.5 ns τ PLH = 3.0RonLC = 3.0(13.3kΩ)(0.3 pF ) = 12.0 ns t f = 3.7RonS C = 3.7(1.98kΩ)(0.3 pF )= 2.20 ns τ PHL = 1.2RonS C = 1.2(1.98kΩ)(0.3 pF )= 0.713 ns τP = 6-44 12.0 + 0.713 = 6.36 ns 2 6.125 ( ) 2 2x10−9 s 3.0RonL + 1.2RonS τP = = C → 3.0RonL + 1.2RonS = = 4000Ω 2 2 10−12 F ⎛ 2 V ⎞ K KS ⎜VGSS − VTNS − L ⎟VL = L (VGSL − VTNL ) Ignore body effect for simplicity. 2⎠ 2 ⎝ ⎛ 2 0.25 ⎞ KL KS ⎜ 2.5 − 0.6 − 0.6 − 2.5 − 0.25 − 0.6) → KS = 4.63KL ⎟0.25 = ( 2 2 ⎠ ⎝ τ PLH + τ PHL 3.0 1.2 + = 4000Ω → KL = 5.04x10−4 A/V 2 KL (2.5 − .25 − 0.6) 4.63KL (2.5 − 0.6 − 0.6) ⎛W ⎞ 5.04x10−4 8.41 = ⎜ ⎟ = −5 1 ⎝ L ⎠ L 6.0x10 6.126 VH = 2.5V VL = 0.2V 1 RonL = KL (VGS − VTN ) = RonS = 1 = ⎛W ⎞ 8.41 = 38.9 ⎜ ⎟ = 4.63 1 ⎝ L ⎠S ( ) VTNL = 0.6 + 0.5 0.2 + 0.6 − 0.6 = 0.66V ( 6x10 −5 ( ) 5.72 = 30.4kΩ 1 = 3.95kΩ (4 − 0.2 − 0.66) KS (VGS − VTN ) 2.22 6x10 −5 ) (2.5 − 0.6) t r ≅ 3.7RonLC = 3.7(0.7 pF )(30.4kΩ) = 78.7 ns t f ≅ 3.7RonS C = 3.7(0.7 pF )(3.95kΩ) = 10.2 ns τ PLH ≅ 0.69RonLC = 0.69(0.7 pF )(30.4kΩ)= 14.7 ns τ PHL ≅ 1.2RonS C = 1.2(0.7 pF )(3.95kΩ)= 3.32 ns τP = 14.7 + 3.32 = 9.00 ns 2 6-45 6.127 3.0V 2.0V 1.0V 0V 3.0V 2.0V 1.0V 0V Results: tf = 1.0 ns, tr = 22.3 ns, τPHL = 0.47 ns, τPLH = 4.0 ns, τP = 4.2 ns 6.128 ( ) 2 3x10−9 s 3.6RonL + 1.2RonS τP = = C → 3.6RonL + 1.2RonS = = 6000Ω 2 2 10−12 F ⎛ 2 V ⎞ K KS ⎜VGSS − VTNS − L ⎟VL = L (−VTNL ) Ignore body effect for simplicity. 2⎠ 2 ⎝ ⎛ 0.25 ⎞ KL 2 KS ⎜ 3 − 0.6 − ⎟0.25 = (3) → KS = 7.91KL 2 2 ⎠ ⎝ 3.6 1.2 + = 6000Ω → KL = 2.11x10−4 A/V 2 KL (3) 7.91KL (3 − 0.6) τ PLH + τ PHL ⎛W ⎞ 2.11x10−4 3.52 = ⎜ ⎟ = −5 1 ⎝ L ⎠ L 6.0x10 t r = 8.1RonL 6-46 ⎛W ⎞ 3.52 = 27.8 ⎜ ⎟ = 7.91 1 ⎝ L ⎠S ( ) = 12.8 ns C= 3.52(6x10 )(3) 8.1 10−12 −5 t f = 3.7RonS C = ( ) = 0.924 ns 27.8(6x10 )(3 − 0.6) 3.7 10−12 −5 6.129 ( ) 2 10−9 s 3.6RonL + 1.2RonS τP = = C → 3.6RonL + 1.2RonS = = 10.0kΩ 2 2 0.2x10−12 F ⎛ 2 V ⎞ K KS ⎜VGSS − VTNS − L ⎟VL = L (−VTNL ) Ignore body effect for simplicity. 2⎠ 2 ⎝ ⎛ KL 2 0.20 ⎞ KS ⎜ 3.3 − 0.75 − ⎟0.20 = (2) → KS = 4.08KL 2 2 ⎠ ⎝ τ PLH + τ PHL 1.2 3.6 + = 10kΩ → KL = 1.92x10−4 A/V 2 KL (2) 4.08KL (3.3 − 0.75) ⎛W ⎞ 1.92x10−4 3.19 = ⎜ ⎟ = −5 1 ⎝ L ⎠ L 6.0x10 I DD = ⎛W ⎞ 3.19 = 13.0 ⎜ ⎟ = 4.08 1 ⎝ L ⎠S 3.3(384μA) 2 KL 1.92x10−4 2 −V = 2) = 384μA P = = 0.634 mW ( ( TNL ) 2 2 2 6.130 (a) VTN = 0.6 + 0.5 0.20 + 0.6 − 0.6 = 0.660V ( ) ⎛W ⎞ 2 100x10−6 ⎛W ⎞ 1 ⎜ ⎟ (2.5 − 0.20 − 0.66) → ⎜ ⎟ = 2 ⎝ L ⎠L ⎝ L ⎠ L 1.68 80x10−6 = (b) 80x10 −6 = ⎛W ⎞ 2 100x10−6 ⎛W ⎞ 1 ⎜ ⎟ (2.5 − 0.20 − 0.6) → ⎜ ⎟ = 2 ⎝ L ⎠L ⎝ L ⎠ L 1.81 ⎛W ⎞ ⎛ ⎛W ⎞ 2.3 ⎞ 1 = 100x10−6⎜ ⎟ ⎜4 − 0.20 − 0.66 − ⎟2.3 → ⎜ ⎟ = 2 ⎠ ⎝ L ⎠L ⎝ ⎝ L ⎠ L 5.72 ⎛W ⎞ ⎛ ⎛W ⎞ 2.3 ⎞ 1 (d ) 80x10−6 = 100x10−6⎜⎝ L ⎟⎠ ⎜⎝4 − 0.20 − 0.6 − 2 ⎟⎠2.3 → ⎜⎝ L ⎟⎠ = 5.89 L L (c) 80x10 −6 (e) V TN ( ) = −1+ 0.5 0.20 + 0.6 − 0.6 = −0.940V ⎛W ⎞ 1.81 2 100x10 ⎛W ⎞ ⎜ ⎟ (−0.940) → ⎜ ⎟ = 2 1 ⎝ L ⎠L ⎝ L ⎠L ⎛W ⎞ 1.60 2 100x10−6 ⎛W ⎞ (f ) 80x10−6 = 2 ⎜⎝ L ⎟⎠ (−1) → ⎜⎝ L ⎟⎠ = 1 L L 80x10−6 = −6 6-47 6.131 For VDD = -2.5 V, we have VH = -0.20 V with a power dissipation of 0.20 mW. Since these gates are all ratioed logic design, the ratio of the W/L ratios of the load and switching transistors does not change. We only need to scale both equally to achieve the power level. ⎛ W ⎞ 100 2.22 5.55 = (a) RL = 28.8kΩ | ⎜ ⎟ = 1 ⎝ L ⎠ S 40 1 ⎛W ⎞ 100 1 ⎛ W ⎞ 100 4.71 11.8 1.49 (b) ⎜ ⎟ = = | ⎜ ⎟ = = 1 1 ⎝ L ⎠ L 60 1.68 ⎝ L ⎠ S 60 1 ⎛W ⎞ 100 1 ⎛ W ⎞ 100 1 5.55 (c) ⎜ ⎟ = = | ⎜ ⎟ = 2.22 = 1 ⎝ L ⎠ L 60 5.72 2.29 ⎝ L ⎠ S 60 ⎛W ⎞ 100 1.81 4.53 ⎛ W ⎞ 100 2.22 5.55 (d ) ⎜ ⎟ = = | ⎜ ⎟ = = 1 1 ⎝ L ⎠ L 60 1 ⎝ L ⎠ S 60 1 ⎛W ⎞ 100 1.11 2.78 ⎛ W ⎞ 100 2.22 5.55 (e) ⎜ ⎟ = = | ⎜ ⎟ = = 1 1 ⎝ L ⎠ L 60 1 ⎝ L ⎠ S 60 1 6.132 ⎛2⎞ ⎛ 2 −V ⎞ 1 ⎛ 25x10−6 ⎞ VL = −2.5 + 0.6 = −1.9 V | ⎜ ⎟ 25x10-6 ⎜ −1.9 − (−0.6)− H ⎟(−VH )= ⎜ ⎟ −2.5 − VH − (−0.6) 2 ⎠ 4⎝ 2 ⎠ ⎝1⎠ ⎝ ( ) 9VH2 − 24.6VH + 3.61 = 0 → VH = −0.156 V 6.133 Pretend this is an NMOS gate with VDD = 3.3V and VL = 0.33V [ )] ( VH = 3.3 − 0.6 + 0.75 VH + 0.7 − 0.7 → VH = 2.08V ( ) 0.1mW = 30.3μA 3.3V ⎛W ⎞ 0.303 2 40μA ⎛ W ⎞ 1 30.3μA = = ⎜ ⎟ (3.3 − 0.33 − 0.734) → ⎜ ⎟ = 1 3.30 2 ⎝ L ⎠L ⎝ L ⎠L ⎛W ⎞ ⎛ ⎛W ⎞ 1.75 0.33⎞ 30.3μA = 40μA⎜ ⎟ ⎜ 2.08 − 0.60 − ⎟0.33 → ⎜ ⎟ = 2 ⎠ 1 ⎝ L ⎠S ⎝ ⎝ L ⎠S VTNL = 0.6 + 0.75 0.33 + 0.7 − 0.7 = 0.734 | I DD = 6-48 ( ) 6.134 [ )] ( VL = −VTPL | VL = − −0.6 − 0.75 2.5 − VL + 0.7 − 0.7 → VL = 1.07V ⎛W ⎞ ⎛ K 'p ⎛W ⎞ 2 VDS ⎞ K ⎜ ⎟ ⎜VGS − VTPS − ⎟VDS = ⎜ ⎟ (VGSL − VTPL ) 2 ⎠ 2 ⎝ L ⎠L ⎝ L ⎠S ⎝ 2 VH − 2.5⎞ 1 ⎛ 1⎞ 3⎛ ⎜1.07 − 2.5 − (−0.6)− ⎟(VH − 2.5) = ⎜ ⎟(VH + VTPL ) 2 ⎝ 3⎠ 1⎝ 2 ⎠ ' p ( ) VTPL = −0.6 − 0.75 VH + 0.7 − 0.7 Solving the last two equations iteratively : VH = 2.30 V 6.135 Y is low only when both A and B are high : Y = AB or Y = AB. Alternatively, Y is high when either A or B is low : Y = A + B = AB 6.136 Y is high only when both A and B are low : Y = AB or Y = A + B 6.137 0.0V -0.5V -1.0V -1.5V 2 0V VL = -1.90 and VH = -0.156 agree with the hand calculations in Prob. 6.132 6.138 -0.0V -1.0V -2.0V 3 0V VH = -0.33 and VL -2.08 agree with the design values in Prob. 6.133. 6-49 6.139 0.0V -0.5V -1.0V -1.5V 2 0V tr = 16.8 ns, tf = 560 μs, τPLH = 11.7 ns, τPHL = 60 ns, τP = 35.9 ns 6.140 -0.0V -1.0V -2.0V -3.0V 0s 0 2us tr = 46 ns, tf = 1.1 6-50 0 4us 0 6us 0 8us 1 0us 1 2us s, τPLH = 21 ns, τPHL = 122 ns, τP = 72 ns 1 4us 1 6us 1 8us 2 0us CHAPTER 7 7.1 ( −14 cm 2 ⎞ (3.9) 8.854x10 F / cm 3.9εo ⎛ K = µ nC = µ n = µn = ⎜ 500 ⎟ Tox Tox V − sec ⎠ 10x10−9 m(100cm / m) ⎝ ' n εox " ox ) F A µA = 173 x 10−6 2 = 173 2 V − sec V V ⎛ ⎞ µ 200 µA µA K 'p = µ pCox" = p Kn' = ⎜ ⎟173 2 = 69.1 2 µn V V ⎝ 500 ⎠ Kn' = 173x10−6 7.2 V DD vI (5 V) B V S D p+ p+ n+ vo D SS (0 V) S n+ n+ B p+ p-well PMOS transistor Ohmic contact NMOS transistor n-type substrate Ohmic contact 7.3 ⎛ pA ⎞ A = ⎜ 500 2 ⎟(1cm x 0.5cm)= 250 pA cm ⎠ ⎝ ⎛ pA ⎞ (b) I = I S A + 20x106 ⎜⎝100 cm2 ⎟⎠ 2x10−4 cm 5x10−4 cm = 250 + 200 = 450 pA (a) I = I S ( ) ( )( ) (c) Same as (b) 7.4 F ⎞⎛ 10mm 0.1cm ⎞ ⎛ 3.9⎜ 8.854 x10 −14 ⎟⎜ ⎟(1µm ) ⎛ ε ox A ⎞ 3.9ε o LW cm ⎠⎝ 2 mm ⎠ ⎝ ⎟⎟ = 3 =3 C = 3⎜⎜ = 0.518 pF t ox 1µm ⎝ t ox ⎠ 7.5 (a) VH = 2.5 V, VL = 0 V (b) VH = 1.8 V, VL = 0 V 7-1 7.6 (a) VH = 2.5 V, VL = 0 V (b) Same as (a). VH and VL don't depend upon W/L in a CMOS gate. 7.7 (a) VH = 3.3 V, VL = 0 V (b) Same as (a). VH and VL don't depend upon W/L in a CMOS gate. 7.8 (a) VH = 2.5V | VL = 0V | For MN , VGS = 0, so MN is cut off. For MP , VGS = −2.5, VDS = 0V and VTP = -0.60V. For VDS < VGS - VTP , M P is in the triode region. (b) For M N , VGS = 2.5, VDS = 0V and VTN = 0.60V. For VDS < VGS - VTN , M N is in the triode region. For MP , VGS = 0, so M P is cut off. (c) For M N , VGS = 1.25, VDS = 1.25 V and VTN = 0.60V. For VDS > VGS - VTN , MN is saturated. For MP , VGS = −1.25, VDS = -1.25V and VTP = -0.75V. For VDS > VGS - VTP , MP is saturated. 7.9 (a) VH = 3.3V | VL = 0V | For MN , VGS = 0, so MN is cut off. For MP , VGS = −3.3, VDS = 0V and VTP = -0.75V. For VDS < VGS - VTP , M P is in the triode region. (b) For M N , VGS = 3.3, VDS = 0V and VTN = 0.75V. For VDS < VGS - VTN , MN is in the triode region. For MP , VGS = 0, so MP is cut off. (c) For M N , VGS = 1.65, VDS = 1.65 V and VTN = 0.75V. For VDS > VGS - VTN , MN is saturated. For MP , VGS = −1.65, VDS = -1.65V and VTP = -0.75V. For VDS > VGS - VTP , MP is saturated. 7.10 (a) VH = 0 V, VL = -5.2 V (b) Same as (a). VH and VL don't depend upon W/L in a CMOS gate. 7-2 7.11 For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: (a) Both transistors are saturated with VDS = VGS K 2 2 Kn vI − VTN ) = p (v I − VDD − VTP ) so vI − VTN = VDD − vI + VTP ( 2 2 V + VTN + VTP 2.5 + 0.6 − .6 vO = vI = DD = = 1.25V 2 2 2 2 K 100µA ⎛ 2 ⎞ (b) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(1.25 − 0.6) = 42.3µA K 2 2 40µA ⎛ 5 ⎞ Checking I DP = p (vI − VDD − VTp ) = ⎜ ⎟(1.25 − 2.5 + 0.6) = 42.3µA 2 2 ⎝1⎠ (c) For K n = 2.5K p , 2.5K p K 2 2 vI − VTN ) = p (vI − VDD − VTP ) or 1.58(vI − VTN )= VDD − vI + VTP ( 2 2 V + 1.58VTN + VTP 2.5 + 1.58(0.6)+ (−0.6) vO = vI = DD = = 1.104V 2.58 2.58 2 100µA ⎛ 2 ⎞ (d ) I DN = 2 ⎜⎝ 1 ⎟⎠(1.104 − 0.6) = 25.4µA | Check by finding IDP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(1.104 − 2.5 + 0.6) = 25.3µA 2 ⎝ 1⎠ 7.12 (a) For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: K 2 2 Kn vI − VTN ) = p (vI − VDD − VTP ) and vI − VTN = VDD − v I + VTP i () ( 2 2 V + VTN + VTP 3.3 + 0.75 − 0.75 vO = vI = DD = = 1.65V 2 2 2 2 K 100µA ⎛ 2 ⎞ (ii) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(1.65 − 0.75) = 81µA 2 2 K 40µA ⎛ 5 ⎞ Checking : I DP = P (vI − VDD + VTP ) = ⎜ ⎟(1.65 − 3.3 + 0.75) = 81µA 2 2 ⎝ 1⎠ For Kn = 2.5 Kp, 7-3 2.5K p K 2 2 vI − VTN ) = p (v I − VDD − VTP ) so 1.58(vI − VTN )= VDD − vI + VTP ( 2 2 V + 1.58VTN + VTP 3.3 + 1.58(0.75)+ (−0.75) vO = vI = DD = = 1.448V 2.58 2.58 2 100µA ⎛ 2 ⎞ (iv ) I DN = 2 ⎜⎝ 1 ⎟⎠(1.448 − 0.75) = 48.7µA | Check by finding I DP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(1.448 − 3.3 + 0.75) = 48.6µA 2 ⎝1⎠ (iii ) (b) For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: K 2 2 Kn vI − VTN ) = p (vI − VDD − VTP ) and vI − VTN = VDD − v I + VTP i () ( 2 2 V + VTN + VTP 2.5 + 0.6 − 0.6 vO = vI = DD = = 1.25V 2 2 2 2 K 100µA ⎛ 2 ⎞ (ii ) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(1.25 − 0.6) = 42.3µA K 2 2 100µA ⎛ 2 ⎞ Checking : I DP = p (vI − VDD + VTP ) = ⎜ ⎟(1.25 − 2.5 + 0.6) = 42.3µA 2 2 ⎝1⎠ For Kn = 2.5 Kp, 2.5K p K 2 2 vI − VTN ) = p (v I − VDD − VTP ) and 1.58(v I − VTN ) = VDD − v I + VTP ( 2 2 V + 1.58VTN + VTP 2.5 + 1.58(0.60)+ (−0.60) vO = vI = DD = = 1.104V 2.58 2.58 2 100µA ⎛ 2 ⎞ (iv ) I DN = 2 ⎜⎝ 1 ⎟⎠(1.104 − 0.60) = 25.4µA | Check by finding I DP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(1.104 − 2.5 + 0.60) = 25.3µA 2 ⎝1⎠ (iii ) 7-4 7.13 (a) For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: K 2 2 Kn vI − VTN ) = p (vI − VDD − VTP ) and vI − VTN = VDD − v I + VTP i () ( 2 2 V + VTN + VTP 1.8 + 0.5 − 0.5 vO = vI = DD = = 0.90V 2 2 2 2 K 100µA ⎛ 2 ⎞ (ii ) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(0.9 − 0.5) = 16.0µA 2 2 K 40µA ⎛ 5 ⎞ Checking : I DP = P (vI − VDD − VTP ) = ⎜ ⎟(0.9 −1.8 + 0.5) = 16.0µA 2 2 ⎝ 1⎠ For Kn = 2.5 Kp, 2.5K p K 2 2 vI − VTN ) = p (v I − VDD − VTP ) so 1.58(vI − VTN )= VDD − vI + VTP ( 2 2 V + 1.58VTN + VTP 1.8 + 1.58(0.5)+ (−0.5) vO = vI = DD = = 0.810V 2.58 2.58 2 100µA ⎛ 2 ⎞ (iv ) I DN = 2 ⎜⎝ 1 ⎟⎠(0.810 − 0.5) = 96.2µA | Check by finding I DP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(0.8101−1.8 + 0.5) = 96.0µA 2 ⎝1⎠ (iii ) (b) For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: K 2 2 Kn vI − VTN ) = p (vI − VDD − VTP ) and vI − VTN = VDD − v I + VTP i () ( 2 2 V + VTN + VTP 2.5 + 0.75 − 0.65 vO = vI = DD = = 1.30V 2 2 2 2 K 100µA ⎛ 2 ⎞ (ii ) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(1.30 − 0.75) = 30.3µA K 2 2 40µA ⎛ 5 ⎞ Checking : I DP = p (vI − VDD + VTP ) = ⎜ ⎟(1.30 − 2.5 + 0.65) = 30.3µA 2 2 ⎝ 1⎠ 7-5 For Kn = 2.5 Kp, 2.5K K 2 2 (iii ) 2 p (vI − VTN ) = 2p (vI − VDD − VTP ) and 1.58(vI − VTN )= VDD − vI + VTP V + 1.58VTN + VTP 2.5 + 1.58(0.75)+ (−0.65) vO = vI = DD = = 1.176V 2.58 2.58 2 100µA ⎛ 2 ⎞ (iv ) I DN = 2 ⎜⎝ 1 ⎟⎠(1.176 − 0.75) = 18.2µA | Check by finding I DP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(1.176 − 2.5 + 0.65) = 18.2µA 2 ⎝1⎠ (c) For vI = vO, both transistors will be saturated since vGS = vDS for each device. Equating the drain currents with Kn = Kp yields: K 2 2 Kn vI − VTN ) = p (vI − VDD − VTP ) and vI − VTN = VDD − v I + VTP i () ( 2 2 V + VTN + VTP 2.5 + 0.65 − 0.75 vO = vI = DD = = 1.20V 2 2 2 2 K 100µA ⎛ 2 ⎞ (ii ) I DN = 2n (vI − VTN ) = 2 ⎜⎝ 1 ⎟⎠(1.20 − 0.65) = 30.3µA K 2 2 40µA ⎛ 5 ⎞ Checking : I DP = p (vI − VDD + VTP ) = ⎜ ⎟(1.20 − 2.5 + 0.75) = 30.3µA 2 2 ⎝ 1⎠ For Kn = 2.5 Kp, 2.5K p K 2 2 vI − VTN ) = p (v I − VDD − VTP ) and 1.58(v I − VTN ) = VDD − v I + VTP ( 2 2 V + 1.58VTN + VTP 2.5 + 1.58(0.65)+ (−0.75) vO = vI = DD = = 1.076V 2.58 2.58 2 100µA ⎛ 2 ⎞ (iv ) I DN = 2 ⎜⎝ 1 ⎟⎠(1.076 − 0.65) = 18.2µA | Check by finding I DP : 2 40µA ⎛ 2 ⎞ I DP = ⎜ ⎟(1.076 − 2.5 + 0.75) = 18.2µA 2 ⎝1⎠ (iii ) 7.14 *PROBLEM 7.14 - CMOS INVERTER TRANSFER CHARACTERISTICS VIN 1 0 DC 0 VDD 3 0 DC 2.5 M1 2 1 0 0 MOSN W=2U L=1U M2 2 1 3 3 MOSP W=2U L=1U .DC VIN 0 2.5 .01 *.DC VIN 2.16 2.17 .0001 .MODEL MOSN NMOS KP=10E-5 VTO=0.6 GAMMA=0 .MODEL MOSP PMOS KP=4E-5 VTO=-0.6 GAMMA=0 7-6 .PRINT DC V(2) .END Result: vI = 1.104 V 2.5K p K 2 2 vI − VTN ) = p (VDD − vI + VTP ) and 1.58(vI − VTN )= VDD − vI + VTP ( 2 2 V + 1.58VTN + VTP 2.5 + 1.58(0.6)+ (−0.6) vO = vI = DD = = 1.10 V 2.58 2.58 7.15 (a) VH = 3.3 V. For vO = VL , assume MP is saturated and MN is in the triode region. ⎛ ⎞⎛ K 'p ⎛1⎞ 2 VL ⎞ ' 4 ⎜ ⎟(−3.3 + 0.6) = Kn⎜ ⎟⎜3.3 − 0.6 + ⎟VL 2 ⎝1⎠ 2⎠ ⎝ 1 ⎠⎝ −5 ⎛ 7.29 ⎞ ⎛ 4x10 VL ⎞ 2 = 2.7 + ⎜ ⎟ ⎜ ⎟VL and rearranging : VL + 5.4VL − 0.729 = 0 −5 2⎠ 2 10x10 ⎝ 4 ⎠ ⎝ ( ) VL = 0.132V. Checking the assumptions - For MN , 3.3 - 0.6 > 0.132. Triode region is correct. For MP , VGS - VTP = -3.3 + 0.6 = -2.7V and VDS = 0.132 - 3.3 = -3.17V. Saturation region operation is correct. (b) V H = 2.5 V. For vO = VL , assume MP is saturated and MN is in the triode region. ⎛ ⎞⎛ K 'p ⎛1⎞ 2 VL ⎞ ' 4 ⎜ ⎟(−2.5 + 0.6) = Kn⎜ ⎟⎜2.5 − 0.6 + ⎟VL 2 ⎝1⎠ 2⎠ ⎝ 1 ⎠⎝ −5 ⎛ 3.61⎞ ⎛ 4x10 VL ⎞ 2 = 1.9 + ⎜ ⎟ ⎜ ⎟VL and rearranging : VL + 3.8VL − 0.361 = 0 −5 2⎠ 2 10x10 ⎝ 4 ⎠ ⎝ ( ) VL = 0.0928V. Checking the assumptions - For MN , 2.5 - 0.6 > 0.0928. Triode region is correct. For MP , VGS - VTP = -2.5 + 0.6 = -1.9V and VDS = 0.0928 - 2.5 = -2.41V. Saturation region operation is correct. 7-7 7.16 For the NMOS device 1.5 mA + +5 V 0.6 V - ⎛ ⎞⎛ ⎞ ⎟0.6 = 1.5x10 (100x10 )⎜⎝WL ⎟⎠ ⎜⎝5 − 0.6 − 0.6 2 ⎠ −6 n ⎛W ⎞ 61.0 ⎜ ⎟ = 1 ⎝ L ⎠n For the PMOS device +5 V + 2.6 V 60 µA ⎛W ⎞ ⎛ 2.6 ⎞ −5 40x10−6 ⎜ ⎟ ⎜ 5 − 0.6 − ⎟2.6 = 6x10 2 L ⎝ ⎠ p⎝ ⎠ ( ) ⎛W ⎞ 1 ⎜ ⎟ = ⎝ L ⎠ p 5.37 7-8 −3 7.17 +2.5 V vO +2.5 V Kn = 2000 µA and K p = 1600 µA . V V2 Therefore the output will be forced below VDD /2. 2 For both transistors, VGS − VTN = 1.9V. Assume that both devices are in the linear region. ⎛ 40 ⎞ ⎛ ⎛ 20 ⎞ VO − 2.5 ⎞ -5 -5 ⎜ ⎟ 4x10 ⎜ −2.5 + 0.6 − ⎟(VO − 2.5)= ⎜ ⎟ 10x10 2 1 1 ⎝ ⎠ ⎝ ⎠ ⎝ ⎠ ( ) ( Rearranging : VO2 −14.2VO + 13 = 0 ⇒ ⎛ ⎞ )⎜⎝2.5 − 0.6 − V2 ⎟⎠V O O VO = 0.9836V | VDSN = 0.984V | VDSP = −1.52V and the assumed operating regions are correct. ⎛ 40 ⎞ ⎛ 0.9836 − 2.5 ⎞ I DP = ⎜ ⎟ 4x10-5 ⎜ −2.5 + 0.6 − ⎟(0.9836 − 2.5)= 2.77 mA, and checking 2 ⎝1⎠ ⎝ ⎠ ⎛ 20 ⎞ ⎛ 0.9836 ⎞ I DN = ⎜ ⎟ 10x10-5 ⎜ 2.5 − 0.6 − ⎟0.9836 = 2.77 mA. 2 ⎠ ⎝1⎠ ⎝ 7.18 KR = ( ) ( ) 2(2.5)(2.5 − 0.6 − 0.6) 2.5 − 2.5(0.6)− 0.6 Kn = 2.5 | VIH = − = 1.22V 2.5 −1 Kp 2.5 −1 1+ 3 2.5 ( ) ( ) ( ) (2.5 + 1)(1.22)− 2.5 − 2.5(0.6)+ 0.6 = 0.174V 2(2.5) 2( 2.5 )(2.5 − 0.6 − 0.6) 2.5 − 2.5(0.6)− 0.6 = − = 0.902V 2.5 −1 (2.5 −1)( 2.5 + 3) (2.5 + 1)(0.902)+ 2.5 − 2.5(0.6)+ 0.6 = 2.38V = VOL = VIL VOH NMH = VOH 2 − VIH = 2.38 −1.22 = 1.16 V NML = VIL − VOL = 0.902 − 0.174 = 0.728 V 7-9 7.19 VDD − VTN − 3VTP 3.3-0.75-3(-0.75) = = 1.20 V 4 4 V + 3VTN + VTP 3.3+3(0.75)-0.75 and NM L = DD = = 1.20 V 4 4 2(2.5)(3.3 − 0.75 − 0.75) 3.3 − 2.5(0.75)− 0.75 K − = 1.61V (b) KR = K n = 2.5 | VIH = 2 . 5 − 1 p (2.5 − 1) 1 + 3(2.5) (a ) For K = 1: NM H = R ( ) (2.5 + 1)(1.61)− 3.3 − 2.5(0.75)+ 0.75 = 0.242V 2(2.5) 2( 2.5 )(3.3 − 0.75 − 0.75) 3.3 − 2.5(0.75)− 0.75 = − = 1.17V . 5 − 1 2 2 . 5 − 1 2 . 5 + 3 ( )( ) (2.5 + 1)(1.17)+ 3.3 − 2.5(0.75)+ 0.75 = 3.14V = VOL = VIL VOH NM H = VOH 2 − VIH = 3.14 − 1.61 = 1.53 V NM L = VIL − VOL = 1.17 − 0.242 = 0.928V 7.20 4.0V 3.0V 2.0V 1.0V 0V 0V V(M2:d) 0.5V V(M4:d) V(M6:d) 1.0V 2.0V 1.5V V_VI 7-10 2.5V 3.0V 3.5V 7.21 (a) CMOS Noise Margins (VDD = 3.3 V, VTN = 0.75 V, VTP = -.75 V) 2.5 2 1.5 NMH NML 1 0.5 0 0 2 4 6 8 10 12 KR (b) CMOS Noise Margins (VDD = 2.0 V, VTN = 0.5 V, VTP = -0.5 V) 1.4 1.2 1 0.8 NML NMH 0.6 0.4 0.2 0 0 2 4 6 8 10 12 KR 7-11 7.22 (a) t r ≅ 3.6 RonP C = t f ≅ 3.6 RonN C = 3.6(0.25 pF ) 3.6C = = 2.36 ns K p VGS − VTP 5 4 x10−5 −2.5 + 0.6 ( ) 3.6(0.25 pF ) 3.6C = = 2.36 ns Kn (VGS − VTN ) 2 10−4 (2.5 − 0.6) ( ) tr = 0.788 ns 3 t 0.788 + 0.788 τ PHL ≅ 1.2 RonN C = f = 0.788 ns τ P = = 0.788 ns 2 3 3.6(0.25 pF ) 3.6C (b) tr ≅ 3.6 RonP C = K V − V = 5 4 x10−5 −2.0 + 0.6 = 3.21 ns p GS TP τ PLH = 1.2 RonP C = ( t f ≅ 3.6 RonN C = ) 3.6(0.25 pF ) 3.6C = = 3.21 ns Kn (VGS − VTN ) 2 10−4 (2 − 0.6) ( ) tr = 1.07 ns 3 t 1.07 + 1.07 τ PHL ≅ 1.2 RonN C = f = 1.07 ns τ P = = 1.07 ns 2 3 3.6(0.25 pF ) 3.6C (c) tr ≅ 3.6 RonP C = K V − V = 5 4 x10−5 −1.8 + 0.6 = 3.75 ns p GS TP τ PLH = 1.2 RonP C = ( t f ≅ 3.6 RonN C = ) 3.6(0.25 pF ) 3.6C = = 3.75 ns Kn (VGS − VTN ) 2 10−4 (1.8 − 0.6) ( ) tr = 1.25 ns 3 t 1.25 + 1.25 τ PHL ≅ 1.2 RonN C = f = 1.25 ns τ P = = 1.25 ns 2 3 τ PLH = 1.2 RonP C = 7.23 t r ≅ 3.6 RonP C = 3.6(0.5 pF ) 3.6C = = 11.9 ns K p VGS − VTP 2 4 x10−5 −2.5 + 0.6 t f ≅ 3.6 RonN C = 3.6(0.5 pF ) 3.6C = = 4.74 ns Kn (VGS − VTN ) 2 10−4 (2.5 − 0.6) ( ) ( ) tr = 3.96 ns 3 t 3.96 + 1.58 τ PHL ≅ 1.2 RonN C = f = 1.58 ns τ P = = 2.77 ns 2 3 τ PLH = 1.2 RonP C = 7-12 7.24 t r ≅ 3.6 RonP C = 3.6(0.15 pF ) 3.6C = = 1.42 ns K p VGS − VTP 5 4 x10−5 −2.5 + 0.6 t f ≅ 3.6 RonN C = 3.6(0.15 pF ) 3.6C = = 1.42 ns Kn (VGS − VTN ) 2 10−4 (2.5 − 0.6) ( ) ( ) tr = 0.474 ns 3 t 0.474 + 0.474 τ PHL ≅ 1.2 RonN C = f = 0.474 ns τ P = = 0.474 ns 2 3 τ PLH = 1.2 RonP C = 7.25 t r ≅ 3.6 RonP C = 3.6(0.2 pF ) 3.6C = = 1.41 ns K p VGS − VTP 5 4 x10−5 −3.3 + 0.75 t f ≅ 3.6 RonN C = 3.6(0.2 pF ) 3.6C = = 1.41 ns Kn (VGS − VTN ) 2 10−4 (3.3 − 0.75) ( ) ( ) tr = 0.470 ns 3 t 0.470 + 0.470 τ PHL ≅ 1.2 RonN C = f = 0.470 ns τ P = = 0.470 ns 2 3 τ PLH = 1.2 RonP C = 7.26 For the symmetrical design, τ PLH = τ PHL and τ P = τ PHL 3ns = 1.2(1pF) ⎛W ⎞ −6 ⎜ ⎟ 100 x10 (2.5 − 0.6) ⎝ L ⎠n ( ) ⎛ W ⎞ 2.11 ⎛W ⎞ ⎛ W ⎞ 5.26 →⎜ ⎟ = | ⎜ ⎟ = 2.5⎜ ⎟ = 1 1 ⎝ L ⎠n ⎝ L ⎠p ⎝ L ⎠n t r = t f = 3τ PHL = 9.00 ns 7-13 7.27 (a ) For the symmetrical design, τ PLH = τ PHL and τ P = τ PHL 1ns = 1.2(10pF) ⎛W ⎞ −6 ⎜ ⎟ 100 x10 (2.5 − 0.6) ⎝ L ⎠n ( ) ⎛ W ⎞ 63.2 ⎛W ⎞ ⎛ W ⎞ 158 →⎜ ⎟ = | ⎜ ⎟ = 2.5⎜ ⎟ = 1 1 ⎝ L ⎠n ⎝ L ⎠p ⎝ L ⎠n t r = t f = 3τ PHL = 3.00 ns (b) 1ns = ⎛W ⎞ 1.2(10pF) ( ) −6 ⎜ ⎟ 100 x10 (3.3 − 0.7) ⎝ L ⎠n ⎛W ⎞ 46.2 ⎛W ⎞ ⎛W ⎞ 115 →⎜ ⎟ = | ⎜ ⎟ = 2.5⎜ ⎟ = 1 1 ⎝ L ⎠n ⎝ L ⎠p ⎝ L ⎠n t r = t f = 3τ PHL = 3.00 ns 7.28 For the symmetrical design, τ PLH = τ PHL and τ P = τ PHL 0.2ns = 1.2(0.1pF ) ⎛W ⎞ −6 ⎜ ⎟ 100 x10 (1.5 − 0.5) ⎝ L ⎠n ( ) ⎛ W ⎞ 6.00 ⎛W ⎞ ⎛ W ⎞ 15.0 →⎜ ⎟ = | ⎜ ⎟ = 2.5⎜ ⎟ = 1 1 ⎝ L ⎠n ⎝ L ⎠p ⎝ L ⎠n t r = t f = 3τ PHL = 0.600 ns 7.29 For the symmetrical design, τ PLH = τ PHL and τ P = τ PHL 0.4ns = 1.2(0.1pF) ⎛W ⎞ −6 ⎜ ⎟ 100 x10 (2.5 − 0.6) ⎝ L ⎠n ( ) ⎛ W ⎞ 1.58 ⎛W ⎞ ⎛ W ⎞ 3.95 →⎜ ⎟ = | ⎜ ⎟ = 2.5⎜ ⎟ = 1 1 ⎝ L ⎠n ⎝ L ⎠p ⎝ L ⎠n t r = t f = 3τ PHL = 1.20 ns 7.30 *PROBLEM 7.30 - CMOS INVERTER DELAY *SIMULATION USES THE MODELS IN APPENDIX B VIN 1 0 PULSE (0 2.5 0 0.1N 0.1N 10N 20N) VDD 3 0 DC 2.5 M1 2 1 0 0 MOSN W=4U L=2U AS=16P AD=16P M2 2 1 3 3 MOSP W=10U L=2U AS=40P AD=40P CL 2 0 100FF .OP .TRAN 0.1N 20N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N 7-14 +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PRINT TRAN V(2) .PROBE V(1) V(2) .END Results: tr = 1.7 ns, tf = 2.25 ns, τPHL = 1.1 ns, τPLH = 0.9 ns τ PHL = 1.2RonnC τ PLH = 1.2RonpC 1.1x10−9 ⎛ 2 ⎞ −6 = C1 = ⎜ ⎟ 50x10 (2.5 − 0.91)= 146 fF | Inverter is symmetrical, so 1.29Ronn 1.2 ⎝ 1 ⎠ 9x10−10 ⎛ 5 ⎞ 146 + 130 τ −6 C2 = PLH = fF = 138 fF ⎜ ⎟ 20x10 (2.5 − 0.77) = 130 fF | C = 2 1.2Ronp 1.2 ⎝ 1 ⎠ τ PHL ( ( ) ) 7.31 *PROBLEM 7.31 - FIVE CASCADED INVERTERS *SIMULATION USES THE MODELS IN APPENDIX B VDD 1 0 DC 2.5 VIN 2 0 PULSE (0 2.5 0 0.1N 0.1N 10N 20N) * MN1 3 2 0 0 MOSN W=16U L=2U AS=64P AD=64P MP1 3 2 1 1 MOSP W=40U L=2U AS=160P AD=160P *AS=4UM*W - AD=4UM*W CL1 3 0 100FF * MN2 4 3 0 0 MOSN W=16U L=2U AS=64P AD=64P MP2 4 3 1 1 MOSP W=40U L=2U AS=160P AD=160P CL2 4 0 100FF * MN3 5 4 0 0 MOSN W=16U L=2U AS=64P AD=64P MP3 5 4 1 1 MOSP W=40U L=2U AS=160P AD=160P CL3 5 0 100FF * MN4 6 5 0 0 MOSN W=16U L=2U AS=64P AD=64P MP4 6 5 1 1 MOSP W=40U L=2U AS=160P AD=160P CL4 6 0 100FF * MN5 7 6 0 0 MOSN W=16U L=2U AS=64P AD=64P MP5 7 6 1 1 MOSP W=40U L=2U AS=160P AD=160P CL5 7 0 100FF .OP .TRAN 0.025N 20N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P 7-15 .PROBE V(2) V(3) V(5) V(6) .END First inverter : t r = 0.83 ns, t f = 1.4 ns, τ PLH = 0.35 ns, τ PHL = 0.42 ns Fourth inverter : t r = 0.96 ns, t f = 1.0 ns, τ PLH = 0.64 ns, τ PHL = 1.1 ns τ PHL = 1.2RonnC C1 = C2 = τ PHL τ PLH = 1.2RonpC 0.42x10−9 ⎛ 8 ⎞ −6 ⎜ ⎟ 50x10 (2.5 − 0.91)= 223 fF | The inverter is symmetrical, so 1 1.2 ⎝ ⎠ −9 ⎛ 0.35x10 20 ⎞ 223 + 202 −6 = fF = 212 fF ⎜ ⎟ 20x10 (2.5 − 0.77)= 202 fF | C = 2 1.2 ⎝ 1 ⎠ ( = 1.2Ronn τ PLH 1.2Ronp ) ( ) The average capacitance of 212 fF that is required to fit the results is consistent with the device capacitances calculated by SPICE. The approximate 3:1 relationship holds between rise/fall times and the propagation delay times in the first inverter. The first inverter response is faster than that of the fourth inverter because of the rapid rise and fall times on the input signal. The first inverter response is closest to our model used for hand calculations. However, the response of inverter four would be more representative of the actual logic situation. 7.32 (a) 100W = 1µW / gate 100 x10 6 gates (b) I = 100W = 55.6 A 1.8V 7.33 (a) 5W = 2.5µW / gate 2x106 gates (b) C = 2.5x10-6 ( 2.52 5x106 ) 2 P = CVDD f ;C = 2.5x10-6 ( 3.32 5x106 ) = 45.9 fF = 80.0 fF 7.34 ⎛ pA ⎞ A = ⎜ 400 2 ⎟(0.5cm x 1cm)= 200 pA cm ⎠ ⎝ ⎛ pA ⎞ (b) I = I S A + 75x106 ⎜⎝150 cm2 ⎟⎠ 2.5x10−4 cm 1x10−4 cm = 200 + 281 = 481pA (a ) I = I S ( ) ( )( ) (c) Same as (b) 7.35 ( )( )101 2 (a) P = 64CVDD f = 64 25x10-12 2.52 7.36 7-16 −8 = 1.00 W ( )( )101 (b) P = 64 25x10-12 3.32 −8 = 1.74 W Peak current occurs for vO = v I . Assume both transistors are saturated since vO = vI . 2 2 20 ⎛ 40x10−6 ⎞ 20 ⎛100x10−6 ⎞ − V = v ⎜ ⎟( I ⎜ ⎟(v I − VDD − VTP ) →1.58(v I − VTN ) = VDD − v I + VTP TN ) 1⎝ 2 ⎠ 2 1⎝ ⎠ 3.3 + 1.58(0.6)+ (−0.6) VDD + 1.58VTN + VTP = = 1.414 V 2.58 2.58 2 20 ⎛ 100x10−6 ⎞ iD = ⎜ ⎟(1.414 − 0.6) = 663 µA 1⎝ 2 ⎠ (a) v O = vI = Checking the current : iD = (b) v O = vI = 2 20 ⎛ 40x10−6 ⎞ ⎜ ⎟(1.414 − 3.3 + 0.6) = 662 µA | Within roundoff error. 1⎝ 2 ⎠ 2.5 + 1.58(0.6)+ (−0.6) 2.58 = 1.104 V | iD = 2 20 ⎛ 100x10−6 ⎞ ⎜ ⎟(1.104 − 0.6) = 254 µA 2 1⎝ ⎠ 2 20 ⎛ 40x10−6 ⎞ Checking the current : iD = ⎜ ⎟(1.104 − 2.5 + 0.6) = 253 µA | Within roundoff error. 1⎝ 2 ⎠ 7.37 For a symmetrical inverter, the peak current occurs for vO = v I = VDD . 2 Assume both transistors are saturated since vO = vI . 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ ⎟(vI − VTN ) = ⎜ ⎟(v I − VDD − VTP ) → (vI − VTN )= VDD − vI + VTP ⎜ 1⎝ 2 1⎝ 2 ⎠ ⎠ VDD + VTN + VTP 3.3 + (0.7)+ (−0.7) = = 1.65 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ = ⎜ ⎟(1.65 − 0.7) = 90.3 µA Checking : iDP = ⎜ ⎟(1.65 − 3.3 + 0.7) = 90.3 µA 2 1⎝ 1⎝ 2 ⎠ ⎠ (a) v O iDN VDD + VTN + VTP 2 + (0.5)+ (−0.5) = = 1.00 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ = ⎜ ⎟(1.00 − 0.5) = 25.0 µA Checking : iDP = ⎜ ⎟(1.0 − 2 + 0.5) = 25.0 µA 2 1⎝ 1⎝ 2 ⎠ ⎠ (b) v O iDN = vI = = vI = 7-17 7.38 For a symmetrical inverter, the peak current occurs for vO = v I = VDD . 2 Assume both transistors are saturated since vO = vI . 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ ⎜ ⎟(vI − VTN ) = ⎜ ⎟(v I − VDD − VTP ) → (vI − VTN )= VDD − vI + VTP 1⎝ 1⎝ 2 ⎠ 2 ⎠ VDD + VTN + VTP 2.5 + (0.7)+ (−0.7) = = 1.25 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ = ⎜ ⎟(1.25 − 0.7) = 30.3 µA Checking : iDP = ⎜ ⎟(1.25 − 2.5 + 0.7) = 30.3 µA 2 1⎝ 1⎝ 2 ⎠ ⎠ (a) v O iDN VDD + VTN + VTP 2.5 + (0.65)+ (−0.55) = = 1.30 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ 1.30 − 0.65 = ⎜ = 42.3 µ A Checking : i = ⎟( ⎜ ⎟(1.3 − 2.5 + 0.55) = 42.3 µA ) DP 2 1⎝ 1⎝ 2 ⎠ ⎠ (b) v O iDN = vI = = vI = 7.39 For the inverter, the peak current occurs for vO = vI . Assume both transistors are saturated since vO = vI . 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ ⎜ ⎟(vI − VTN ) = ⎜ ⎟(v I − VDD − VTP ) → (vI − VTN )= VDD − vI + VTP 2 1⎝ 1⎝ 2 ⎠ ⎠ VDD + VTN + VTP 2 + (0.55)+ (−0.45) = = 1.05 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ = ⎜ = 25.0 µ A Checking : i = 1.05 − 0.55 ⎟( ⎟(1.05 − 2 + 0.45) = 25.0 µA ⎜ ) DP 2 1⎝ 1⎝ 2 ⎠ ⎠ (a) v O iDN VDD + VTN + VTP 2 + (0.45)+ (−0.55) = = 0.950 V 2 2 2 2 2 ⎛100x10−6 ⎞ 5 ⎛ 40x10−6 ⎞ = ⎜ ⎟(0.95 − 0.45) = 25.0 µA Checking : iDP = ⎜ ⎟(0.95 − 2 + 0.55) = 25.0 µA 2 1⎝ 1⎝ 2 ⎠ ⎠ (b) v O iDN = vI = = vI = 7.40 ( ) 2 (0.25 pF ) 2.5 = 0.313 pJ P = CV 2 f = 0.25 pF 2.52 108 = 156 µW CVDD = ( ) DD 5 5 2 0.25 pF ) 22 ( CVDD 2 = 0.200 pJ P = CVDD f = (0.25 pF ) 22 108 = 100 µW (b) PDP ≅ 5 = 5 2 0.25 pF ) 1.82 ( CVDD 2 = 0.163 pJ P = CVDD f = (0.25 pF ) 1.82 108 = 81.0 µW (c) PDP ≅ 5 = 5 (a) PDP ≅ 2 () ( ) 7-18 ( )( ) ( )( ) ( )( ) 7.41 ( ) 2 0.2 pF ) 3.32 ( CVDD = 0.290 pJ (a) PDP ≅ 7.5 = 7.5 (b) f max ≅ 1 7.5τ P τ PLH = 1.2RonP C = 1.2(0.2 pF ) 1.2C = = 0.471 ns K p VGS − VTP 5 4x10−5 −3.3 + 0.75 τ PHL ≅ 1.2RonN C = 1.2(0.2 pF ) 1.2C = = 0.471 ns Kn (VGS − VTN ) 2 10−4 (3.3 − 0.75) τP = ( ) ( ) 0.471+ 0.471 = 0.471 ns 2 f max ≅ ( )( 1 1 = = 283 MHz 7.5τ P 7.5(0.471ns) ) 2 f = (0.2 pF ) 3.32 2.83x108 = 616 µW (c) P = CVDD 7.42 ( ) 2 (0.15 pF ) 2.5 = 0.125 pJ CVDD PDP ≅ = a () 7.5 7.5 2 (b) f max ≅ 1 7.5τ P τ PLH = 1.2RonP C = 1.2(0.15 pF ) 1.2C = = 0.474ns K p VGS − VTP 5 4x10−5 −2.5 + 0.6 τ PHL ≅ 1.2RonN C = 1.2(0.15 pF ) 1.2C = = 0.474 ns Kn (VGS − VTN ) 2 10−4 (2.5 − 0.6) τP = ( ) ( ) 0.474 + 0.474 = 0.474 ns 2 f max ≅ ( )( 1 1 = = 282 MHz 7.5τ P 7.5(0.474ns) ) 2 f = (0.15 pF ) 2.52 2.82x108 = 264 µW (c) P = CVDD 7.43 *PROBLEM 7.41 - INVERTER PDP VDD 1 0 DC 2.5 VIN 2 0 PULSE (0 2.5 0 0.1N 0.1N 15N 30N) * MN1 3 2 0 0 MOSN W=4U L=1U AS=8P AD=8P MP1 3 2 1 1 MOSP W=4U L=1U AS=8P AD=8P C1 3 0 200fF *AS=2UM*W - AD=2UM*W * MN2 4 2 0 0 MOSN W=8U L=1U AS=16P AD=16P MP2 4 2 1 1 MOSP W=8U L=2U AS=16P AD=16P C2 4 0 200fF * MN3 5 2 0 0 MOSN W=16U L=1U AS=32P AD=32P MP3 5 2 1 1 MOSP W=16U L=1U AS=32P AD=32P 7-19 C3 5 0 200fF * MN4 6 2 0 0 MOSN W=32U L=1U AS=64P AD=64P MP4 6 2 1 1 MOSP W=32U L=1U AS=64P AD=64P C4 6 0 200fF * MN5 7 2 0 0 MOSN W=64U L=1U AS=128P AD=128P MP5 7 2 1 1 MOSP W=64U L=1U AS=128P AD=128P C5 7 0 200fF * MN6 8 2 0 0 MOSN W=100U L=1U AS=200P AD=200P MP6 8 2 1 1 MOSP W=100U L=1U AS=200P AD=200P C6 8 0 200fF * MN7 9 2 0 0 MOSN W=320U L=1U AS=640P AD=640P MP7 9 2 1 1 MOSP W=2320U L=1U AS=640P AD=640P C7 9 0 200fF * MN9 11 2 0 0 MOSN W=1000U L=1U AS=2000P AD=2000P MP9 11 2 1 1 MOSP W=1000U L=1U AS=2000P AD=2000P C9 11 0 200fF * .OP .TRAN 0.025N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(4) V(5) V(6) V(7) V(8) V(9) V(10) V(11) .END At small device sizes, the power-delay product will be CVDD2 = 1.25 pJ. 7-20 Delay versus Device Size 1.00E+01 1.00E+00 Series1 1.00E-01 1 10 100 1000 W/L of NMOS & PMOS Devices 7.44 ∆T = C∆V KCox" WL∆V = ⎛W ⎞ 2 I 1 µnCox" ⎜ ⎟(VGS − VTN ) 2 ⎝ L⎠ | Let W' = αW , L' = αL, Tox' = αTox , V' = αV K (αW )(αL)(α∆V ) C '∆V ' = = α∆T ' 2 I 1 ⎛ αW ⎞ µn ⎜ ⎟(αVGS − αVTN ) 2 ⎝ αL ⎠ ⎛W ⎞ 2 2 V V ε ⎛W ⎞ P = VI = µnCox" ⎜ ⎟(VGS − VTN ) = µn ox ⎜ ⎟(VGS − VTN ) 2 2 Tox ⎝ L ⎠ ⎝ L⎠ 2 αV ε ⎛ αW ⎞ 2 P'= µn ox ⎜ ⎟(αVGS − αVTN ) = α P αTox ⎝ αL ⎠ 2 ∆T '= PDP'= P'∆T'= (α∆T )α 2 P = α 3 P∆T = α 3 PDP 7-21 7.45 ∆T = KCox" WL∆V C∆V = | Let W' = αW , L' = αL, Tox' = αTox ⎛ ⎞ 2 I 1 W µnCox" ⎜ ⎟(VGS − VTN ) 2 ⎝ L⎠ K (αW )(αL)(∆V ) C '∆V ' = = α 2∆T ' ⎛ ⎞ 2 I 1 αW µn ⎜ ⎟(VGS − VTN ) 2 ⎝ αL ⎠ ⎛W ⎞ 2 2 V V ε ⎛W ⎞ P = VI = µnCox" ⎜ ⎟(VGS − VTN ) = µn ox ⎜ ⎟(VGS − VTN ) 2 2 Tox ⎝ L ⎠ ⎝ L⎠ 2 ε ⎛ αW ⎞ V P P ' = µn ox ⎜ ⎟(VGS − VTN ) = 2 αTox ⎝ αL ⎠ α ∆T ' = ( PDP ' = P ' ∆T ' = α 2∆T )αP = αP∆T = α PDP 7.46 (Note: Simulation time needs to be extended.) *PROBLEM 7.46 - FIVE CASCADED INVERTERS VDD 1 0 DC 2.5 VIN 2 0 PULSE (0 2.5 0 0.1N 0.1N 25N 50N) * MN1 3 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MP1 3 2 1 1 MOSP W=5U L=1U AS=40P AD=40P C1 3 0 0.25P *AS=8UM*W - AD=8UM*W * MN2 4 3 0 0 MOSN W=2U L=1U AS=16P AD=16P MP2 4 3 1 1 MOSP W=5U L=1U AS=40P AD=40P C2 4 0 0.25P * MN3 5 4 0 0 MOSN W=2U L=1U AS=16P AD=16P MP3 5 4 1 1 MOSP W=5U L=1U AS=40P AD=40P C3 5 0 0.25P * MN4 6 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MP4 6 5 1 1 MOSP W=5U L=1U AS=40P AD=40P C4 6 0 0.25P * MN5 7 6 0 0 MOSN W=2U L=1U AS=16P AD=16P MP5 7 6 1 1 MOSP W=5U L8U AS=40P AD=40P C5 7 0 0.25P .OP .TRAN 0.025N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N 7-22 +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(5) V(6) .END 3.0V 2.0V 1.0V 0V First inverter : t r = 4.6 ns, t f = 5.4 ns, τ PLH = 2.6 ns, τ PHL = 2.1 ns Fourth inverter : t r = 5.8 ns, t f = 6.3 ns, τ PLH = 4.2 ns, τ PHL = 4.7 ns τ PHL = 1.2RonnC = τ PLH = 1.2RonpC = 0.25x10−12 ⎛ 2⎞ −6 ⎜ ⎟ 50x10 (2.5 − 0.91) 1 ⎝ ⎠ ( ) 0.25x10−12 = 1.58ns ⎛ 5⎞ −6 ⎜ ⎟ 20x10 (2.5 − 0.77) ⎝ 1⎠ ( ) = 1.45ns The inverters are slower than the equations predict because of the additional capacitances in the transistor models. The effective capacitance appears to be approximately 0.4 pF. The delay of the interior inverter is substantially slower than predicted by the formula because of the slow rise and fall times of the driving signals. 7-23 7.47 (Note: Simulation time needs to be extended.) *PROBLEM 7.47(a) - FIVE CASCADED SYMMETRICAL INVERTERS VDD 1 0 DC 5 VIN 2 0 PULSE (0 5 0 0.1N 0.1N 75N 150N) * MN1 3 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MP1 3 2 1 1 MOSP W=5U L=1U AS=40P AD=40P C1 3 0 1P *AS=8UM*W - AD=8UM*W * MN2 4 3 0 0 MOSN W=2U L=1U AS=16P AD=16P MP2 4 3 1 1 MOSP W=5U L=1U AS=40P AD=40P C2 4 0 1P * MN3 5 4 0 0 MOSN W=2U L=1U AS=16P AD=16P MP3 5 4 1 1 MOSP W=5U L=1U AS=40P AD=40P C3 5 0 1P * MN4 6 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MP4 6 5 1 1 MOSP W=5U L=1U AS=40P AD=40P C4 6 0 1P * MN5 7 6 0 0 MOSN W=2U L=1U AS=16P AD=16P MP5 7 6 1 1 MOSP W=5U L=1U AS=40P AD=40P C5 7 0 1P .OP .TRAN 0.025N 150N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(5) V(6) .END 7-24 First inverter : t r = 17.7 ns, t f = 20.7 ns, τ PLH = 8.1 ns, τ PHL = 9.9 ns Fourth inverter : t r = 22.3 ns, t f = 24.2 ns, τ PLH = 16.3 ns, τ PHL = 18.3 ns τ PHL = 1.2 RonnC = τ PLH = 1.2 RonpC = 1.2 x10−12 ⎛ 2⎞ −6 ⎜ ⎟ 50 x10 (2.5 − 0.91) ⎝ 1⎠ ( ) 1.2 x10−12 = 7.6 ns ⎛ 5⎞ −6 ⎜ ⎟ 20 x10 (2.5 − 0.77) ⎝ 1⎠ ( ) = 6.9 ns 3.0V 2.0V 1.0V 0V -1.0V 0s V(CL1:2) 20ns V(CL2:2) V(CL3:2) 40ns V(CL4:2) 60ns V(CL5:2) V(VI:+) 80ns 100ns 120ns 140ns 160ns Time The inverters are slower than the equations predict because of the additional capacitances in the transistor models. The delay of the interior inverter is substantially slower than predicted by the formula because of the slow rise and fall times of the driving signals. *PROBLEM 7.47(b) - FIVE CASCADED MINIMUM SIZE INVERTERS VDD 1 0 DC 5 VIN 2 0 PULSE (0 5 0 0.1N 0.1N 125N 250N) * MN1 3 2 0 0 MOSN W=4U L=2U AS=16P AD=16P MP1 3 2 1 1 MOSP W=4U L=2U AS=16P AD=16P C1 3 0 1P *AS=4UM*W - AD=4UM*W * MN2 4 3 0 0 MOSN W=4U L=2U AS=16P AD=16P MP2 4 3 1 1 MOSP W=4U L=2U AS=16P AD=16P C2 4 0 1P * MN3 5 4 0 0 MOSN W=4U L=2U AS=16P AD=16P MP3 5 4 1 1 MOSP W=4U L=2U AS=16P AD=16P C3 5 0 1P * MN4 6 5 0 0 MOSN W=4U L=2U AS=16P AD=16P MP4 6 5 1 1 MOSP W=4U L=2U AS=16P AD=16P C4 6 0 1P * MN5 7 6 0 0 MOSN W=4U L=2U AS=16P AD=16P 7-25 MP5 7 6 1 1 MOSP W=4U L=2U AS=16P AD=16P C5 7 0 1P .OP .TRAN 0.025N 250N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(5) V(6) .END 3.0V 2.0V 1.0V 0V -1.0V 0s V(CL1:2) V(CL2:2) 50ns V(CL3:2) V(CL4:2) V(CL5:2) 100ns V(VI:+) 150ns 200ns 250ns Time First inverter : t r = 43.7 ns, t f = 20.6 ns, τ PLH = 19.7 ns, τ PHL = 9.7 ns Fourth inverter : t r = 47.5 ns, t f = 31.4 ns, τ PLH = 30.4 ns, τ PHL = 25.7 ns τ PHL = 1.2 RonnC = τ PLH = 1.2 RonpC = 1.2 x10−12 ⎛ 2⎞ −6 ⎜ ⎟ 50 x10 (2.5 − 0.91) ⎝ 1⎠ ( ) 1.2 x10−12 = 7.5 ns ⎛ 2⎞ −6 ⎜ ⎟ 20 x10 (2.5 − 0.77) ⎝ 1⎠ ( ) = 17.3 ns The inverters are slower than the equations predict because of the additional capacitances in the transistor models. The delay of the interior inverter is substantially slower than predicted by the formula because of the slow rise and fall times of the driving signals. 7-26 7.48 (a) V DD 20 1 D 20 1 C 20 1 B 20 1 vo 2 1 2 1 B C 2 1 D 2 1 (b ) NMOS : 3 ⎛⎜ 2 ⎞⎟ = 6 ⎝1⎠ ⎛ 20 ⎞ 60 | PMOS : 3⎜ ⎟ = 1 ⎝ 1 ⎠ 1 7-27 7.49 (a) V DD D C B A vO D C B A W ⎛2⎞ 8 = 4⎜ ⎟ = L ⎝1⎠ 1 W 5 PMOS : = L 1 (b ) NMOS : W = 2(4)⎛⎜ 2 ⎞⎟ = 16 L ⎝1⎠ 1 (a ) NMOS : PMOS : 7-28 W ⎛ 5 ⎞ 10 = 2⎜ ⎟ = L ⎝1⎠ 1 7.50 V DD D NMOS: C PMOS: 1 5 2 1 B Z = A+B+C+D A PMOS: C B D 0.4 ⎛ 2 ⎞ 1 2 | NMOS: ⎜ ⎟= 4 ⎝1⎠ 5 1 7.51 VDD C NMOS: 1 3.75 PMOS: 2 1 B Z = A+B+C A B C 7-29 7.52 VDD A B C Z = ABC A B C (W/L)N = 2/1, (W/L)P = 2.5(2/1)/3, = 1.67/1 7.53 VDD D C B A Z = ABCD D C B A (W/L)N = 2/1, (W/L)P = 2.5(2/1)/4, = 1.25/1 7-30 7.54 Output Z is A multiplied by B. A B Z 0 0 0 0 1 0 1 0 0 1 1 1 From the truth table, Z = AB, a two input AND gate. Assuming complemented variables are available, VDD B M = ( A + B ) = AB A NMOS: B PMOS: 4 1 5 1 7.55 (The dc input should be 0 V.) *PROBLEM 7.55 - TWO-INPUT CMOS NOR GATE VDD 1 0 DC 2.5 VA 2 0 DC 0 PULSE (0 2.5 0 0.1N 0.1N 25N 50N) VB 5 0 DC 0 * MNA 4 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MPA 4 2 3 1 MOSP W=10U L=1U AS=80P AD=80P MNB 4 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MPB 3 5 1 1 MOSP W=10U L=1U AS=80P AD=80P CL 4 0 1PF * MNC 6 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MPC 6 5 7 1 MOSP W=10U L=1U AS=80P AD=80P MND 6 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MPD 7 2 1 1 MOSP W=10U L=1U AS=80P AD=80P CL 6 0 1PF * 7-31 .OP .DC VDD 0 2.5 0.01 .TRAN 0.1N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(4) V(6) .END 3.0V 2.0V 1.0V 0V 0V 0.5V V2(C2) 1.0V 1.5V 2.0V 2.5V V2(C3) V_VA 3.0V 2.0V 1.0V 0V 0s V(VA:+) 10ns V2(C3) 20ns V2(C3) 30ns 40ns 50ns 60ns 70ns 80ns 90ns 100ns Time The transitions of the two VTCs are separated by approximately 50 mV. The dynamic characteristics for switching one input with the other constant are essentially identical. The two transitions are virtually identical because of the ideal step inputs: τPHL = 3.6 ns, τPLH = 3.6 ns, tf = 8.1 ns, tr = 7.9 ns. With the inputs switched together, τPHL and tf are reduced by 50% because the two NMOS devices are working in parallel. 7.56 The simulation results show only slight changes from those of Problem 7.55. 7.57 *PROBLEM 7.54 - TWO-INPUT CMOS NAND GATE VDD 1 0 DC 2.5 VA 2 0 DC 0 PULSE (0 2.5 0 0.1N 0.1N 25N 50N) VB 4 0 DC 2.5 * MNA 3 4 0 0 MOSN W=4U L=1U AS=16P AD=16P MPA 5 4 1 1 MOSP W=5U L=1U AS=80P AD=80P 7-32 MNB 5 2 3 0 MOSN W=4U L=1U AS=16P AD=16P MPB 5 2 1 1 MOSP W=5U L=1U AS=80P AD=80P CL1 5 0 1PF * MNC 6 2 0 0 MOSN W=4U L=1U AS=16P AD=16P MPC 7 2 1 1 MOSP W=5U L=1U AS=80P AD=80P MND 7 4 6 0 MOSN W=4U L=1U AS=16P AD=16P MPD 7 4 1 1 MOSP W=5U L=1U AS=80P AD=80P CL2 7 0 1PF * .OP .DC VA 0 2.5 0.01 .TRAN 0.05N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0 +LAMBDA=.02 TOX=41.5N CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0 LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(5) V(7) .END 3.0V 2.0V 1.0V 0V 0V 3.0V 0 5V 1 0V 1 5V 2 0V 2 5V 2.0V 1.0V 0V 0s 10ns 20ns 30ns 40ns 50ns 60ns 70ns 80ns 90ns 100ns The transitions of the two VTCs are separated by approximately 50 mV. The dynamic characteristics for switching one input with the other constant are essentially identical. The two transitions are virtually identical because of the ideal step inputs: τPHL = 3.6 ns, τPLH = 3.7 ns, tf = 8.0 ns, tr = 8.1 ns. With the inputs switched together, τPLH and tr are reduced by 50% because the two PMOS devices are working in parallel 7.58 The simulation results show only slight changes. 7.59 7-33 Worst-case paths are the same as the symmetrical reference inverter: ⎛ 1 ⎞⎛ 15⎞ ⎛ 5⎞ ⎛ 1 ⎞⎛ 4 ⎞ ⎛ 2 ⎞ PMOS tree : ⎜ ⎟⎜ ⎟ = ⎜ ⎟ | NMOS tree : ⎜ ⎟⎜ ⎟ = ⎜ ⎟ | For VDD = 2.5V , ⎝ 3 ⎠⎝ 1 ⎠ ⎝ 1 ⎠ ⎝ 2 ⎠⎝ 1 ⎠ ⎝ 1 ⎠ τ PLH = 1.2 RonP C = 1.2(1.25 pF ) 1.2C = = 3.95ns K p VGS − VTP 5 4 x10−5 −2.5 + 0.6 τ PHL ≅ 1.2 RonN C = 1.2(1.25 pF ) 1.2C = = 3.95 ns Kn (VGS − VTN ) 2 10−4 (2.5 − 0.6) ( ) ( ) Since there is a 2.5 :1 ratio in transistor sizes, τ PLH = τ PHL , τ P = τ PHL = 3.95 ns and t r = t f = 3τ PHL = 3τ P = 11.8 ns 7-34 7.60 (a) A depletion-mode design requires the same number of NMOS transistors in the switching network, but only one load transistor. The depletion-mode design requires 5 transistors total. The CMOS design requires 8 transistors. (b) For the CMOS design, first find the worst - case delay of the circuit in Fig. 7.30 and then scale the result to achieve the desired delay. For VDD = 2.5 V, τ PHL 1.2C τ PLH = K p (VDD + VTP τP = ( ) ( ) 1.2(10 ) = = 23.7 ns ) 1 ⎛⎜ 2 ⎞⎟(40x10 )−2.5 + 0.6 3⎝ 1⎠ 1.2 10−12 1.2C = = = 6.32ns Kn (VDD − VTN ) 1 ⎛ 2 ⎞ −6 ⎜ ⎟ 100x10 (2.5 − 0.6) 2 ⎝1⎠ −12 −6 ⎛ W⎞ 6.32 + 23.7 15.0ns ⎛ 2 ⎞ ⎛ 3.00 ⎞ ns = 15.0ns → ⎜ ⎟ = ⎜ ⎟=⎜ ⎟ 2 ⎝ L ⎠ all 10ns ⎝ 1 ⎠ ⎝ 1 ⎠ 1 = 24.0 Relative Area = 8(3.00)() −−−−− For the depletion - mode design, first assume that τ P is dominated by τ PLH. τ PLH ≅ 2τ P | τ PLH = 3.6RonLC ( ) ( )( ) −12 3.6 10 ⎛W ⎞ 4.50 W = = | Since NMOS is ratioed logic, the ratios ⎜ ⎟ −8 −6 1 L ⎝ L ⎠ L 2 10 40x10 () 1 ⎛W ⎞ (2.22 /1) 4.50 = 5.52 must maintain the ratio in Fig. 7.29(d) : ⎜ ⎟ = 1 ⎝ L ⎠ S (1.81/1) 1 Using this value, τ PHL = ( ) = 1.14ns and 5.52(100x10 )(2.5 - 0.6) 1.2 10-12 -6 20 + 1.14 ns = 10.6ns 2 Rescaling to achieve τ P = 10ns : ⎛W ⎞ 10.6 ⎛ 4.50 ⎞ 4.77 ⎛ W ⎞ 10.6 ⎛ 5.52 ⎞ 5.85 ⎛W ⎞ ⎛ W ⎞ 11.7 | ⎜ ⎟ = | ⎜ ⎟ = 2⎜ ⎟ = ⎜ ⎟ = ⎜ ⎜ ⎟= ⎟= 1 1 1 ⎝ L ⎠ L 10 ⎝ 1 ⎠ ⎝ L ⎠ A 10 ⎝ 1 ⎠ ⎝ L ⎠ B −D ⎝ L ⎠A τP = Relative area = (4.50)() 1 + 3(11.7)() 1 + (5.85)() 1 = 45.5 The CMOS design uses 47% less area and consumes no static power. 7-35 7.61 (a) Y = (A + B)(C + D)(E + F ) W ⎛ 2⎞ 6 = 3⎜ ⎟ = L ⎝ 1⎠ 1 (b) NMOS: PMOS: ⎛ 5 ⎞ 10 W = 2⎜ ⎟ = L ⎝1⎠ 1 A C E D F B 7.62 (a) Y = (A + B)(C + D)E ⎛ 2 ⎞ 18 W = 3(3)⎜ ⎟ = L ⎝ 1⎠ 1 (b) NMOS: A C B D E 7-36 ⎛ W⎞ ⎛ 5⎞ 30 PMOS: ⎜ ⎟ = 2(3)⎜ ⎟ = ⎝ L ⎠ A−D ⎝ 1⎠ 1 ⎛ W⎞ ⎛ 5⎞ 15 ⎜ ⎟ = (3)⎜ ⎟ = ⎝ L ⎠E ⎝ 1⎠ 1 7.63 F G E C E D B C D F G A B A (a) Y = F + G(C + E )+ A(B + D)(C + E )= F + (C + E )(G + A(B + D)) ⎛ W⎞ ⎛ 2 ⎞ 12 ⎛ W ⎞ ⎛ 2⎞ 4 ⎛ W⎞ 1 6 = 3(2)⎜ ⎟ = | ⎜ ⎟ = (2)⎜ ⎟ = | ⎜ ⎟ = = ⎜ ⎟ ⎝ L ⎠ A−E ⎝ 1⎠ 1 ⎝ L ⎠F ⎝ 1 ⎠ 1 ⎝ L ⎠G 1 − 1 1 4 12 ⎛ W⎞ ⎛ 5 ⎞ 40 ⎛ W ⎞ ⎛ ⎞ 1 20 W 1 26.7 PMOS : ⎜ ⎟ = 4(2)⎜ ⎟ = | ⎜ ⎟ = = | ⎜ ⎟ =2 = 1 1 1 1 ⎝ L ⎠ F ,G, B, D ⎝ 1⎠ 1 ⎝ L ⎠A 1 − 2 ⎝ L ⎠C , E − 10 40 10 40 (b) NMOS : 7.64 (a) Y = A + B C + D E + F = AB + CD + EF ( )( )( ) (b) NMOS : ⎛ W⎞ ⎛2⎞ 4 = 2⎜ ⎟ = ⎜ ⎟ ⎝ L ⎠ A−F ⎝1⎠ 1 A C E B D F ⎛ W⎞ ⎛ 5 ⎞ 15 PMOS : ⎜ ⎟ = 3⎜ ⎟ = ⎝ L ⎠ A−F ⎝ 1⎠ 1 7-37 7.65 (a) Y = ACE + ACDF + BDE + BF = (A + C)(B + DF )+ E(F + DB) ( ) ⎛ W⎞ ⎛ 2 ⎞ 18 = 3(3)⎜ ⎟ = ⎜ ⎟ ⎝ L ⎠ A−F ⎝ 1⎠ 1 ⎛ W⎞ ⎛ 5 ⎞ 60 PMOS : ⎜ ⎟ = 4(3)⎜ ⎟ = ⎝ L ⎠ A,C , D, F ⎝ 1⎠ 1 (b) NMOS : ⎛ W⎞ 1 40 = ⎜ ⎟ =2 1 1 1 ⎝ L ⎠ B, E − 15 60 Y C E A F D B 7-38 7.66 VDD 15 1 B 15 1 D F 15 1 A 15 1 15 1 C E 15 1 Y A 4 1 C 6 1 F B 4 1 D 6 1 E 6 1 2 1 7-39 7.67 V DD 20 1 A D 20 1 E F 20 1 G I 20 1 B C 20 1 20 1 20 1 H 20 1 20 1 Y A 6 1 D 4 1 F 6 1 I B 6 1 C 6 1 7-40 E 4 1 G 6 1 H 6 1 2 1 7.68 Y A C Y V DD E B D Gnd (a) An Euler path does not appear to exist. Y A C E Y V DD B D Gnd (b) An Euler path does not appear to exist. F . 7-41 7.69 10011 VDD D B A C E Y D C A E B 10001 VDD D B A C E Y D C A B 7-42 E 11101 V DD D B A C E Y D C A E B 00010 V D DD B A C E Y D C A B E 7-43 7.70 V DD B D F A C E A B C D E F (a) V DD B D F A C E A B C D E F (b) 7-44 V DD B D F A C E A B C D E F (c) VDD B D F A C E A B C D E F (d) 7-45 7.71 + 10 1 A 10 1 B 10 1 D 10 1 C 10 1 E Y 6 1 A D 4 1 E 4 1 6 1 B 6 1 C 7.72 V DD B 40 1 C D 40 1 E 40 1 20 1 A 40 1 Y 24 1 A B 24 1 D 24 1 C 24 1 E 24 1 7-46 7.73 VDD 15 1 B 5 1 A D 15 1 7.5 1 C E 15 1 Y 6 1 A B 6 1 C 3 1 E D 6 1 6 1 7.74 V DD 60 1 E 30 1 A 60 1 C 60 1 D 60 1 B Y 24 1 A E 12 1 C 24 1 D 24 1 8 1 B 7-47 7.75 S = X ⊕ Y = XY + XY and C = XY V Y 10 1 Y DD 10 1 V X 10 1 X DD 10 1 10 1 Y S = (X + Y)(X + Y) X 4 1 Y 4 1 X 4 1 Y 4 1 10 1 C=X+Y X 7-48 2 1 2 1 Y 7.76 Let X = X i Y = Yi Xi Yi Ci-1 Si Ci 0 0 0 0 0 0 0 1 1 0 0 1 0 1 0 0 1 1 0 1 1 0 0 1 0 1 0 1 0 1 1 1 0 0 1 1 1 1 1 1 C = Ci-1 ( ) ( S = (C + (X + Y )(X + Y ))(C + (X + Y )(X + Y )) Si = XYC + XYC + XYC + XYC = C XY + XY + C XY + XY ) i Ci = XY + XC + YC = XY + C (X + Y ) ( )( Ci = X + Y C + XY ) VDD 15 C Y C 1 15 1 15 1 Y 15 1 X 15 X 1 15 1 V DD Y X 15 X 1 15 1 Y 15 1 Y 8 1 Y X 8 1 8 1 Y Y 1 8 1 Y X 4 1 10 1 X 10 1 Y 10 1 Ci X 8 1 8 1 6 1 Y 6 1 X 6 1 8 1 C X C 8 1 C X 1 15 Si X 10 10 1 C 3 1 Y 6 1 4 1 7-49 7.77 N M Output N M Output A B C D O3 O2 O1 O0 A B C D O3 O2 O1 O0 00 00 0000 10 00 0000 00 01 0000 10 01 0010 00 10 0000 10 10 0100 00 11 0000 10 11 0110 01 00 0000 11 00 0000 01 01 0001 11 01 0011 01 10 0010 11 10 0110 01 11 0011 11 11 1001 ( ) O3 = ABCD = A + B + C + D ( O2 = AC = A + C ) ( )( )( )( ) O1 = ABC + ABD + BCD + ACD = A + B + C A + B + D B + C + D A + C + D ( ) O0 = BD = B + D VDD D V V DD DD C C D B O2 O4 O3 A A B C D D ⎛W ⎞ 2 ⎛W ⎞ 20 ⎜ ⎟ = ⎜ ⎟ = ⎝ L ⎠N 1 ⎝ L ⎠P 1 7-50 B C | ⎛W ⎞ 2 ⎛W ⎞ 10 ⎜ ⎟ = ⎜ ⎟ = ⎝ L ⎠N 1 ⎝ L ⎠P 1 | ⎛W ⎞ 2 ⎛W ⎞ 10 ⎜ ⎟ = ⎜ ⎟ = ⎝ L ⎠N 1 ⎝ L ⎠P 1 V DD D D D C C C B B A B A A O1 A C D B C D A B D A B C 7.78 (a) τ PHL = 1.2RonnC = τ PLH = 1.2RonpC = (b) τ PHL ( 1.2 0.4x10−12 PMOS: ) −6 ( ) (2 / 3)(40x10 )−2.5 + 0.6 −6 ( 1.2 0.4x10−12 ) = 9.47ns | τ P = (2 1) 100x10−6 (2.5 − 0.6) 1 τ PLH + τ PLH 2 = 5.37 ns = 1.26ns −12 −6 15 = 1.26ns ( ) 1.2(0.4x10 ) C= = 3.16ns (2 1)(40x10 )−2.5 + 0.6 τ PLH = 1.2Ronp 8 1 (2 1)(100x10 )(2.5 − 0.6) 1.2 0.4x10−12 = 1.2RonnC = NMOS: | τP = τ PLH + τ PLH 2 = 2.21 ns 7-51 7.79 (a) τ PHL = 1.2RonnC = τ PLH = 1.2RonpC = (b) τ PHL ( 1.2 0.18x10−12 ) (2 5)(100x10 )(2.5 − 0.6) −6 ( 1.2 0.18x10−12 ( ) ) = 1.42ns | τ P = (2 /1) 40x10−6 −2.5 + 0.6 = 1.2RonnC = τ PLH = 1.2RonpC = = 2.84ns ( 1.2 0.18x10−12 ) (2 1)(100x10 )(2.5 − 0.6) −6 ( 1.2 0.4x10−12 ( (2 1) 40x10 −6 ) ) −2.5 + 0.6 τ PLH + τ PLH 2 = 2.13 ns = 0.568ns = 3.16ns | τ P = τ PLH + τ PLH 2 = 1.86 ns 7.80 The worst-case NMOS path contains 2 transistors. The worst-case PMOS path contains 3 transistors. 1.2 250x10−15 τ PHL = 1.2RonnC = = 1.58 ns (2 2) 100x10−6 (2.5 − 0.6) ( τ PLH = 1.2RonpC = ( ) ( 1.2 250x10−15 ) ) (2 / 3)(40x10 )−2.5 + 0.6 −6 = 5.92 ns 7.81 The worst-case NMOS path contains 3 transistors. The worst-case PMOS path contains 3 transistors. 1.2 400x10−15 τ PHL = 1.2RonnC = = 3.79 ns (2 3) 100x10−6 (2.5 − 0.6) ( τ PLH = 1.2RonpC = ( ) ( 1.2 400x10−15 ) ) (2 / 3)(40x10 )−2.5 + 0.6 −6 = 9.47 ns 7.82 The worst-case NMOS path contains 3 transistors (ABE or CBD). The worst-case PMOS path also contains 3 transistors. ( ) = 9.47 ns (2 3)(100x10 )(2.5 − 0.6) 1.2(10 ) C= = 23.7 ns (2 / 3)(40x10 )−2.5 + 0.6 τ PHL = 1.2RonnC = 1.2 10−12 −6 −12 τ PLH = 1.2Ronp 7-52 −6 | τP = τ PLH + τ PLH 2 = 16.6 ns 7.83 The worst-case NMOS path contains 3 transistors. 1.2 10−12 τ PHL = 1.2RonnC = = 9.47 ns −6 2 3 100x10 2.5 − 0.6 ( ) ( ) ( ( ) ) 7.84 Student PSPICE will only accept 5 inverters. *PROBLEM 7.84(a) - FIVE CASCADED INVERTERS VDD 1 0 DC 2.5 VIN 2 0 PULSE (0 2.55 0 0.1N 0.1N 20N 40N) * MN1 3 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MP1 3 2 1 1 MOSP W=2U L=1U AS=16P AD=16P C1 3 0 200fF *AS=8UM*W - AD=8UM*W * MN2 4 3 0 0 MOSN W=2U L=1U AS=16P AD=16P MP2 4 3 1 1 MOSP W=2U L=1U AS=16P AD=16P C2 4 0 200fF * MN3 5 4 0 0 MOSN W=2U L=1U AS=16P AD=16P MP3 5 4 1 1 MOSP W=2U L=1U AS=16P AD=16P C3 5 0 200fF * MN4 6 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MP4 6 5 1 1 MOSP W=2U L=1U AS=16P AD=16P C4 6 0 200fF * MN5 7 6 0 0 MOSN W=2U L=1U AS=16P AD=16P MP5 7 6 1 1 MOSP W=2U L=1U AS=16P AD=16P C5 7 0 200fF * .OP .TRAN 0.025N 40N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(4) V(10) V(11) .END (a) 7-53 3.0V 2.0V 1.0V 0V -1.0V 0s V(CL1:2) 5ns V(CL2:2) 10ns V(CL3:2) 15ns 20ns V(CL4:2) V(CL5:2) V(VI:+) 25ns 30ns 35ns 40ns 45ns 50ns Time (b) 3.0V 2.0V 1.0V 0V -1.0V 0s V(VI:+) 5ns V(CL1:2) 10ns V(CL2:2) 15ns V(CL3:2) 20ns V(CL4:2) 25ns V(CL5:2) 30ns 35ns 40ns 45ns 50ns 55ns 60ns Time (a) The minimum size inverters yield P = 5.8 ns. (b) The symmetrical inverters yield τP = 3.7 ns. Note that these results are larger than the delay equation estimate because of the slope of the waveforms. 7-54 7.85 (a) (b) V DD CLK V DD Z = AB CLK A B Z=A+B B A CLK CLK 7-55 7.86 (a) (b) V DD V DD CLK CLK A A B B Z = A + B = AB Z = A + B = AB CLK CLK 7.87 (a) (b) VDD CLK A V DD CLK Z A B C B Z = A+B+C C CLK 7-56 CLK Z = ABC 7.88 (a) (b) V DD CLK A VDD Z = A B C = A+B+C CLK Z B A B C C Z = A + B + C = ABC CLK CLK 7.89 VDD CLK A B C D E F Z = (AB+CD+EF) CLK 7-57 7.90 VDD CLK A B C D E Z = (ABC+DE+F) F CLK 7.91 Charge sharing occurs. Assuming C2 and C3 are discharged (the worst case) (a ) V = (c) V = C1VDD + C2 (0) 2C2VDD 2 2 = VDD | Node B drops to VDD . C1 + C2 2C2 + C2 3 3 ⎛2 ⎞ 2 V 3C ⎜ ⎟ 2 DD C + C V + C 0 ( 1 2 )3 DD 3 ( ) V 1 ⎝3 ⎠ = = DD | Node B drops to VDD . (b) VB = 2C2 + C2 + C2 C1 + C2 + C3 2 2 B B R≥ = C1VDD RC2VDD R = = VDD ≥ VIH → R(VDD − VIH )≥ 2VIH C1 + C2 + C3 RC2 + C2 + C2 R + 2 2VIH 2VIH = VDD − VIH NM H Using VDD = 2.5V , VTN = 0.6V , VTP = −0.6V in Eq. (8.9) : VIH = R≥ 7-58 5(2.5)+ 3(0.6)+ 5(−0.6) 8 2(1.41) = 1.41V | NM H = 2VIH = = 3.05 | C1 ≥ 83.05C2 NM H 0.925 2.5 − 0.6 − 3(−0.6) 4 = 0.925V 7.92 Z = A0 + A1 + A2 V DD Clock A0 A1 A2 Z C 1 7.93 V DD CLK A B C D Z=(A+B)(C+D) CLK 7-59 7.94 V DD CLK A C B D CLK 7-60 Z = AB + CD 7.95 V DD CLK Z A B C D E F CLK 7.96 V DD CLK Z A C E B D F CLK 7.97 N opt = ln 1 CL = ln (4000)= 8.29 → N = 8 | β = (4000)8 = 2.82. Co The relative sizes of the 8 inverters are : 1, 2.82, 7.95, 22.4, 63.2, 178, 503, 1420. Each inverter has a delay of 2.82τ o. The total delay is 8(2.82τ o )= 22.6τ o 7-61 7.98 N opt = ln 1 ⎛ 10 pF ⎞ CL 4 = 3.16. = ln⎜ β = 100 = 4.61 → N = 4 | ( ) ⎟ Co 100 fF ⎝ ⎠ The relative sizes of the 4 inverters are : 1, 3.16, 10.0, 31.6 Each inverter has a delay of 3.16τ o. The total delay is 4(3.16τ o )= 12.6τ o Note, N = 5 yields β = 2.51 and the total delay is 5(2.51τ o ) = 12.6τ o . However, the area will be significantly larger. See Prob. 7.100. 7.99 N opt 1 ⎛ 40 pF ⎞ CL = ln = ln⎜ ⎟ = 6.69 → N = 6 | β = (800)6 = 2.82. Co ⎝ 50 fF ⎠ The relative sizes of the 8 inverters are: 1, 2.82, 7.95, 22.4, 63.2, 178, 503, 1420. Each inverter has a delay of 2.82τ o. The total delay is 8(2.82τ o )= 22.6τ o . Note, N = 7 yields β = 2.60 and the total delay is 7(2.60τ o ) = 18.2τ o. However, the area will be significantly larger. See Prob. 7.100. 7.100 AT = Ao (1+ β + β 2 + ...+ β N −1 )= Ao β N −1 β −1 1000 −1 = 462Ao 3.1623 −1 1000 −1 For N = 7, β = 10001/7 = 2.6827 | A = Ao = 594 Ao 2.6827 −1 Since the two values of N give similar delays, N = 6 would be used For N = 6, β = 10001/6 = 3.1623 | A = Ao because of it requires significantly less area. 7.101 ⎡⎛ 20 ⎞ ⎤−1 −6 (a) Ronn = K V − V = ⎢⎜⎝ 1 ⎟⎠ 100x10 (2.5 − 0.6)⎥ = 263 Ω ⎦ n ( GS TN ) ⎣ 1 (b) R onp = 1 K p VGS − VTP ( ) −1 ⎡⎛ 20 ⎞ ⎤ = ⎢⎜ ⎟ 40x10−6 −2.5 + 0.6 ⎥ = 658 Ω ⎣⎝ 1 ⎠ ⎦ ( ) (c) A resistive channel exists connecting the source and drain. 7-62 7.102 Gon = Gonn + Gonp = Kn (VGSN − VTN )* ( (VGSN − VTN )> 0) + K p (VTP − VGSP )* ( (VTP − VGSP )> 0) VGSN = 2.5 − VI [ ( VSBN = VI VGSP = −VI VTN = 0.6 + 0.5 VI + 0.6 − 0.6 (a) R on )] VBSN = 2.5 − VI [ ( VTP = −0.6 − 0.5 2.5 − VI + 0.6 − 0.6 )] will be the largest for VI = 1 V VTN = 0.845V VTP = −0.937V ( ) ( ) 10 −4 10 10 (2.5 −1− 0.845)+ 4x10−5 (−0.937 + 1) → Ron = 1470Ω 1 1 (b) Ron will be the largest for the VI at which the NMOS transistor just cuts off : Gon = [ )] ( 2.5 − VI = 0.6 + 0.5 VI + 0.6 − 0.6 → VI = 1.554V Gon = ( VTN = 0.947V VTP = −0.834V ) 10 4x10−5 (−0.834 + 1.554)→ Ron = 3470Ω 1 7.103 Gon = Gonn + Gonp = Kn (VGSN − VTN )* ( (VGSN − VTN )> 0) + K p (VTP − VGSP )* ( (VTP − VGSP ) > 0) VGSN = 2.5 − VI [ VSBN = VI VGSP = −VI ( VTN = 0.75 + 0.5 VI + 0.6 − 0.6 )] VBSN = 2.5 − VI [ ( VTP = −0.75 − 0.5 2.5 − VI + 0.6 − 0.6 )] The worst cases occur approximately at the point where the PMOS or NMOS transistors just cut off. [ ( )] The NMOS transistor cuts off for 2.5 − VI = 0.75 + 0.5 VI + 0.6 − 0.6 → VI = 1.426V VTP = −1.01V ⎛W ⎞ ⎛W ⎞ 1 240 = ⎜ ⎟ 4x10−5 (−1.01+ 1.426)→ ⎜ ⎟ = 250 ⎝ L ⎠ P 1 ⎝ L ⎠P ( ) [ ( )] The PMOS transistor cuts off for VI = 0.75 + 0.5 2.5 − VI + 0.6 − 0.6 → VI = 1.074V VTN = −1.01V ⎛W ⎞ ⎛W ⎞ 1 96.2 = ⎜ ⎟ 10−4 (2.5 −1.074 −1.01)→ ⎜ ⎟ = 250 ⎝ L ⎠ N 1 ⎝ L ⎠P ( ) 7.104 (a ) The output of the first NMOS transistor will be [ )] ( VI = 2.5 − VTN = 2.5 − 0.75 + 0.55 VI + 0.6 − 0.6 → VI = 1.399V | VTN = 1.10V The output of the other gates reaches this same value. All three nodes = 1.40 V. For the PMOS transistors, the node voltages will all be 2.5 V. (b) The node voltages would all be + 2.5 V. 7-63 7.105 *Figure 7.38(b) - CMOS Latchup VDD 1 0 RC 1 2 25 RL 3 4 2000 RN 2 3 2000 RP 4 0 500 Q1 3 4 0 NBJT Q2 4 3 2 PBJT .DC VDD 0 5 .01 .MODEL NBJT NPN BF=60 BR=.25 IS=1E-15 .MODEL PBJT PNP BF=60 BR=.25 IS=1E-15 .PROBE I(VDD) V(1) V(2) V(3) V(4) .OPTIONS ABSTOL=1E-12 RELTOL=1E-6 VNTOL=1E-6 .END Simulation results from B2SPICE Circuit 7_91-DC Transfer-1 +0.000e+000 (V) +1.000 +2.000 +3.000 +2.000 +1.500 +1.000 +500.000m +0.000e+000 V(1) V(2) V(3) 7.106 *Figure 7.39(b) - CMOS Latchup VDD 1 0 RC 1 2 25 RL 3 4 2000 RN 2 3 200 RP 4 0 50 Q1 3 4 0 NBJT Q2 4 3 2 PBJT .DC VDD 0 5 .01 .MODEL NBJT NPN BF=60 BR=.25 IS=1E-15 .MODEL PBJT PNP BF=60 BR=.25 IS=1E-15 .PROBE I(VDD) V(1) V(2) V(3) V(4) 7-64 VDD +4.000 .OPTIONS ABSTOL=1E-12 RELTOL=1E-6 VNTOL=1E-6 .END Simulation results from B2SPICE – Latchup does not occur! Circuit 7_92-DC Transfer-2 +0.000e+000 (V) +1.000 +2.000 VDD +3.000 +4.000 +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(1) V(2) 7.107 V DD v B n+ V(3) I S V SS D p+ p+ vo D S n+ n+ B p+ p-well PMOS transistor Ohmic contact NMOS transistor Ohmic contact n-type substrate 7-65 7.108 (a) VIH = VIH = 2K R (VDD − VTN + VTP ) (VDD − K RVTN + VTP ) − (K R −1) (K R −1) 1+ 3K R 2K R (VDD − VTN + VTP ) − (VDD − K RVTN + VTP ) 1+ 3K R 0 = 0 (K R −1) 1+ 3K R 3 + VTN 1+ 3K R 2 1+ 3K R 3 (K R −1) 1+ 3K R + 2 1+ 3K R 2(VDD − VTN + VTP ) − (VDD − K RVTN + VTP ) lim VIH = lim K R →1 K R →1 3 2(VDD − VTN + VTP ) − (VDD − VTN + VTP ) + 2VTN 5V + 3VTN + 5VTP 4 lim VIH = = DD K R →1 2 8 2V − VDD − VTN − VTP VDD − VTN + VTP VOL = IH = 2 8 (b) VIL = lim VIL = K R →1 2 K R (VDD − VTN + VTP ) 2 (VDD − K RVTN + VTP ) (K R − 1) (K R − 1) K R + 3 K R (VDD − VTN + VTP ) − (VDD − K RVTN + VTP ) (K R − 1) K R + 3 − KR + 3 = 0 0 2 1 + VTN K R + 3 (VDD − VTN + VTP ) − (VDD − K RVTN + VTP ) 2 KR 2 KR + 3 lim VIL = lim K R →1 K R →1 1 (K R − 1) KR + 3 + 2 KR + 3 lim VIL = K R →1 (VDD − VTN + VTP ) − (VDD − VTN + VTP ) 1 + 2VTN 3V + 5V + 3V TN TP 4 = DD 8 2 2V + VDD − VTN − VTP 7VDD + VTN − VTP VOH = IH = 2 8 3V + 5VTN + 3VTP VDD − VTN + VTP VDD + 3VTN + VTP NM L = VIL − VOL = DD − = 8 8 4 7V + VTN − VTP 5VDD + 3VTN + 5VTP VDD − VTN − 3VTP NM H = VOH − VIH = DD − = 8 8 4 7-66 7.109 (a) For VDD = 5V, VTN = 1V, VTP = −1V τP = ∆τ P τ 0.322C dτ P 0.322C | =− =− P 2 dK n Kn Kn Kn ≈ SτKPn τP | SτKPn = K n dτ P = −1 τ P dK n ∆K n ∆K = − n = −(−0.25) = +0.25 | A 25% decrease in K n will cause Kn Kn a 25% increase in propagation delay. (b) Assuming a symmetrical inverter with VDD = 5V and VTN = 0.75V, τP = ⎡ ⎛ V −V ⎞ 2VTN ⎤ TN −1⎟ + ⎥ ⎢ln⎜ 4 DD VDD K n (VDD − VTN ) ⎣ ⎝ ⎠ VDD − VTN ⎦ τP = ⎡ ⎛ 5 − 0.75 ⎞ 2(0.75) ⎤ 0.289C C −1⎟ + ⎢ln⎜ 4 ⎥= ⎠ 5 − 0.75 ⎦ K n (5 − 0.75) ⎣ ⎝ 5 Kn C ⎡ ⎤ −4 ⎢ ⎥ dτ P τP C 2VDD VDD ⎢ ⎥ = + + 2 ⎛ ⎞ ⎢ dVTN (VDD − VTN ) K n (VDD − VTN ) VDD − VTN V − VTN ) ⎥ −1⎟ ( DD ⎢⎜ 4 ⎥ VDD ⎠ ⎣⎝ ⎦ ⎡ ⎤ ⎛ −4 ⎞ ⎜ ⎟ ⎢ 2(5) ⎥ 0.120C 0.289C C dτ P ⎝ 5⎠ ⎢ ⎥= = + + dVTN (5 − 0.75)K n K n (5 − 0.75) ⎢⎛ 5 − 0.75 ⎞ (5 − 0.75)2 ⎥ Kn −1⎟ ⎜4 ⎢⎣⎝ ⎥ ⎠ 5 ⎦ V dτ P 0.75K n ⎛ 0.120C ⎞ SτVPTN = TN = ⎜ ⎟ = 0.311 τ P dVTN 0.289C ⎝ K n ⎠ ⎛ 0.1 ⎞ ∆VTN ∆τ P ≅ SτKPn = 0.311⎜ ⎟ = 0.0415 = 4.15%. ⎝ 0.75 ⎠ τP VTN A 13% increase in VTN causes an 4.2% increase in τ P . 7.110 *PROBLEM 7.110 - INVERTER DELAY VS RISETIME VDD 1 0 DC 2.5 V1 2 0 PULSE (0 2.5 0 0.1N 0.1N 50N 100N) MN1 3 2 0 0 MOSN W=1U L=1U AS=4P AD=4P MP1 3 2 1 1 MOSP W=1U L=1U AS=4P AD=4P C1 3 0 1PF * V2 4 0 PULSE (0 2.5 0 0.2N 0.2N 50N 100N) MN3 5 4 0 0 MOSN W=1U L=1U AS=4P AD=4P MP3 5 4 1 1 MOSP W=1U L=1U AS=4P AD=4P C3 5 0 1PF * 7-67 V3 6 0 PULSE (0 2.5 0 0.5N 0.5N 50N 100N) MN5 7 6 0 0 MOSN W=1U L=1U AS=4P AD=4P MP5 7 6 1 1 MOSP W=1U L=1U AS=4P AD=4P C5 7 0 1PF * V4 8 0 PULSE (0 2.5 0 1N 1N 50N 100N) MN7 9 8 0 0 MOSN W=1U L=1U AS=4P AD=4P MP7 9 8 1 1 MOSP W=1U L=1U AS=4P AD=4P C7 9 0 1PF * V5 10 0 PULSE (0 2.5 0 2N 2N 50N 100N) MN9 11 10 0 0 MOSN W=1U L=1U AS=4P AD=4P MP9 11 10 1 1 MOSP W=1U L=1U AS=4P AD=4P C9 11 0 1PF * .OP .TRAN 0.025N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(4) V(5) V(6) V(7) V(8) V(9) V(10) V(11) .END tr 0.1 ns 0.2 ns 0.5 ns 1 ns 5 ns 7-68 τP 14.6 ns 14.7 ns 14.7 ns 14.8 ns 15.8 ns CHAPTER 8 8.1 ( )( ) (c) 256Mb = 2 (2 )(2 )= 2 ( ) 3 (a) 256Mb = 28 210 210 = 268,435,456 bits (b) 1Gb = 210 = 1,073,741,824 bits 8 10 10 28 ( ) | 128kb = 2 7 210 = 217 | 228 = 211 = 2048 blocks 17 2 8.2 I≤ 8.3 pA 1mA = 3.73 28 bit 2 bits (a) P = CV (b) P = CV 2 DD f = 64(10pF)(3.3) (1GHz)= 6.97 W 2 DD f = 64(10 pF )(2.5) (3GHz)= 12 W 2 2 8.4 ⎛ 230 ⎞ 2⎛ 1 ⎞ 2 P = CVDD f = ⎜ ⎟(100fF)(2.5V ) ⎜ ⎟ = 28.0 mW ⎝ 0.012s ⎠ ⎝ 2 ⎠ 8.5 "1" = VDD = 3 V | "0": ⎛ 3 − VO 2 VO ⎞ −6 = 100x10 3 − 0.75 − ⎜ ⎟VO → VO = 0.667µV | "0"= 0.667 µV 2⎠ 1 1010 ⎝ ( ) 8-1 8.6 *PROBLEM 8.6 - 6-T Cell VDD 1 0 DC 3 MN1 3 2 0 0 MOSN W=4U L=2U AS=16P AD=16P MP1 3 2 1 1 MOSP W=10U L=2U AS=40P AD=40P MN2 2 3 0 0 MOSN W=4U L=2U AS=16P AD=16P MP2 2 3 1 1 MOSP W=10U L=2U AS=40P AD=40P MN3 3 0 0 0 MOSN W=4U L=2U AS=16P AD=16P MN4 2 0 0 0 MOSN W=4U L=2U AS=16P AD=16P .IC V(3)=1.55V V(2)=1.45V V(1)=3 .OP .TRAN 0.025N 10N UIC .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PRINT TRAN V(2) V(3) .PROBE V(2) V(3) .END 4.0V 3.0V 2.0V 1.0V 0V Time -1.0V 0s 8-2 2ns 4ns 6ns 8ns 10ns Result: t = 1.5 ns 8.7 (a) 3V +3 V (b) 3V 0.7 V 0.7 V 1.5 V 2.3 V 1.5 V 2.3 V First Case : Both transistors are in the linear region ⎛1⎞⎛ 0.7 ⎞ I DS = 25x10−6 ⎜ ⎟⎜ 2.3 − 0.7 − ⎟0.7 = 21.88µA 2 ⎠ ⎝1⎠⎝ ⎛ W ⎞⎛ ⎛W ⎞ 0.8 ⎞ 1 21.88µA = 25x10−6 ⎜ ⎟⎜3 − 0.7 − 0.7 − ⎟0.8 → ⎜ ⎟ ≤ 0.911 = 2 ⎠ 1.10 ⎝ L ⎠⎝ ⎝ L⎠ Second Case : Both transistors are in the linear region ⎛ ⎞⎛ ⎛ ⎞⎛ ⎞ ⎛ ⎞ −0.7)⎞ ( −6 1 ⎜ ⎟(−0.7)= 25x10−6 ⎜ W ⎟⎜3 −1.5 − 0.7 − 0.8 ⎟0.8 → ⎜ W ⎟ ≤ 1.09 10x10 ⎜ ⎟⎜ 0.7 − 3 − (−0.7)− 2 ⎠ 1 2 ⎟⎠ ⎝1⎠⎝ ⎝ L ⎠⎝ ⎝ L⎠ ⎛W ⎞ 1 So ⎜ ⎟ ≤ ⎝ L ⎠ 1.10 8-3 8.8 *Problem 8.8 - WRITING THE CMOS SRAM VWL 6 0 DC 0 PULSE(0 3 1NS 1NS 1NS 100NS) VDD 3 0 DC 3 VBL1 4 0 DC 0 VBL2 5 0 DC 3 CBL1 4 0 500FF CBL2 5 0 500FF *Storage Cell MCN1 2 1 0 0 MOSN W=1U L=1U AS=4P AD=4P MCP1 2 1 3 3 MOSP W=1U L=1U AS=4P AD=4P MCN2 1 2 0 0 MOSN W=1U L=1U AS=4P AD=4P MCP2 1 2 3 3 MOSP W=1U L=1U AS=4P AD=4P MA1 4 6 2 0 MOSN W=1U L=1U AS=4P AD=4P MA2 5 6 1 0 MOSN W=1U L=1U AS=4P AD=4P * .OP .TRAN 0.01NS 20NS .NODESET V(1)=3 V(2)=0 .MODEL MOSN NMOS KP=2.5E-5 VTO=.70 GAMMA=0.5 +LAMBDA=.05 TOX=20N +CGSO=4E-9 CGDO=4E-9 CJ=2.0E-4 CJSW=5.0E-10 .MODEL MOSP PMOS KP=1.0E-5 VTO=-.70 GAMMA=0.75 +LAMBDA=.05 TOX=20N +CGSO=4E-9 CGDO=4E-9 CJ=2.0E-4 CJSW=5.0E-10 .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 4.0V 3.0V 2.0V 1.0V 0V Time -1.0V 0s 2ns 4ns 6ns 8ns 10ns Small voltage transients occur on both cell storage nodes which die out in 5 - 7 ns. 8-4 8.9 (a ) The transistor will fully discharge CC : VC 0 = 0 V ( = 0.6 + 0.5( 2.5 + 0.6 − ) 0.6 )= 1.09V | V VC1 = 2.5 − VTN = 2.5 − 0.6 − 0.5 VC1 + 0.6 − 0.6 → VC1 = 1.55V | "1"= 1.55 V For VC1 = 2.5V ,VTN W/L ≥ 2.5 + 1.09 = 3.59 V 8.10 For "0" = 0V, the bias across the source-substrate junction is 0 V, so the leakage current would be 0 and the "0" state is undisturbed. For a "1" corresponding to a positive voltage, a reverse bias across the source-substrate junction, and the diode leakage current will tend to destroy the "1" state. iL C n + n "OFF" + 8.11 ( CDG ) VG C VC = 2.5 − VTN = 2.5 − 0.7 − 0.5 VC + 0.6 − 0.6 → VC = 1.47V ∆VC = 1 sCC 1 1 + sCC sCGS ∆VW / L = GS ∆VW / L −2.5 = = −1.43 V 75 fF CC 1+ 1+ 100 fF CGS CC 8.12 QI = 60 fF (0V )+ 7.5 pF (2.5V ) | QF = 7.56 pF (VF ) | QF = QI → VF = VF = 2.48 V | ∆V = 7.5 pF 0.06 2.5V − 2.5V = −2.5 = −19.8 mV 7.56 pF 1.56 8.13 (a) "1"= +3.3 V (b) "1"= +2.5 V 7.5 pF 2.5V 7.56 pF ( = 0.7 + 0.5( 2.5 − V ) 0.6 )→ V | VC = −VTP = 0.7 + 0.5 3.3 − VC + 0.6 − 0.6 → VC = 1.14V | "0"= 1.14 V | VC = −VTP C + 0.6 − C = 1.03V | "0"= 1.03 V 8-5 8.14 Note that the simulation results in Fig. 9.28 assume that the word line is also driven higher than 3 V. For this case: (a) V (b) V C TN ( ) = 5 − VTN = 5 − 0.7 − 0.5 VC + 0.6 − 0.6 → VC = 3.66 V ( ) = 0.7 − 0.5 1.3 + 0.6 − 0.6 = 1.00V VGS − VTN = 5 −1.3 −1.00 = 2.7V | VDS = 3.7 −1.3 = 2.4V → linear region ⎛1⎞⎛ 2.4 ⎞ iDS = 60x10−6 ⎜ ⎟⎜ 5 −1.3 −1.00 − ⎟2.4 = 216 µA which agrees with the text. 2 ⎠ ⎝1⎠⎝ 8.15 (a) "0"= +0 V | V = 3 − V = 3 − 0.7 − 0.5( V + 0.6 − 0.6 )→ V = 1.90V | "1"= 1.90 V (b) A "0" will have 0 V across the drain - substrate junction, so no leakage occurs. C TN C C A "1" will have a reverse bias of 1.9 V across the junction, so the junction leakage will tend to destroy the "1" level. (Note that this discussion ignores subthreshold leakage through the FET which has not been discussed in the text.) 8.16 (a) "1"= +5 V | V = −V = 0.8 + 0.65( 5 − V (b) V = −0.8 − 0.65( 5 + 0.6 − 0.6 )= −1.83V C TP TP C ) + 0.6 − 0.6 → VC = 1.60V | "0"= +1.60 V | VW/L ≤ −1.83V 8.17 ⎛1⎞⎛ 0.6 ⎞ Original : iD = 60x10−6 ⎜ ⎟⎜ 3 −1.3 −1− ⎟0.6 = 14.4µA 2 ⎠ ⎝1⎠⎝ ⎛ 1⎞⎛ 2.4 ⎞ New : iD = 60x10−6 ⎜ ⎟⎜5 −1.3 −1− ⎟2.4 = 216µA. 2 ⎠ ⎝ 1⎠⎝ 2.4 5 −1.3 −1−1.2 1.5 = = 3.75 | VDS ratio : =4 Gate drive terms: 0.6 3 −1.3 −1− 0.3 0.4 Improved gate drive yields a 3.75 times improvement, although it is reduced by the larger VDS term. Improved drain - source voltage yields a 4 times improvement. 4 x 3.75 = 15. 8.18 2⎛ 1 ⎞ 2 f = (0.5) 230 (100fF)(2.5V ) ⎜ P = CVDD ⎟ = 33.6 mW ⎝ 0.01s ⎠ ( ) 8-6 8.19 *Problem 8.19 - 4-T Refresh SRAM VWL 3 0 DC 0 PULSE(0 3 1NS 1NS 1NS 6NS) VBL 4 0 DC 3 VBLB 5 0 DC 3 CC1 1 0 50FF CC2 2 0 50FF *Storage Cell MCN1 2 1 0 0 MOSN W=4U L=2U AS=16P AD=16P MCN2 1 2 0 0 MOSN W=4U L=2U AS=16P AD=16P MA1 4 3 2 0 MOSN W=4U L=2U AS=16P AD=16P MA2 5 3 1 0 MOSN W=4U L=2U AS=16P AD=16P .IC V(1)=0 V(2)=1 V(3)=0 V(4)=3 V(5)=3 .OP .TRAN 0.01NS 20NS UIC .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .PROBE V(1) V(2) V(3) V(4) V(5) .END 4.0V Note the very slow recovery due to relatively high threshold and gamma values relative to the power supply voltage. 3.0V vWL 2.0V D 1.0V D 0V Time -1.0V 0s 5ns 10ns 15ns 20ns 8.20 *Problem 8.20 4-T READ ACCESS VPC 7 0 DC 3 PULSE(3 0 1NS .5NS .5NS 100NS) VWL 6 0 DC 0 PULSE(0 3 2NS .5NS .5NS 100NS) VDD 3 0 DC 3 CBL1 4 0 1PF CBL2 5 0 1PF *Storage Cell MCN1 2 1 0 0 MOSN W=4U L=2U AS=16P AD=16P MCN2 1 2 0 0 MOSN W=4U L=2U AS=16P AD=16P 8-7 MA1 4 6 2 0 MOSN W=4U L=2U AS=16P AD=16P MA2 5 6 1 0 MOSN W=4U L=2U AS=16P AD=16P CC1 1 0 50FF CC2 2 0 50FF * *Sense Amplifier MSN1 4 5 0 0 MOSN W=4U L=2U AS=16P AD=16P MSP1 4 5 3 3 MOSP W=4U L=2U AS=16P AD=16P MSN2 5 4 0 0 MOSN W=4U L=2U AS=16P AD=16P MSP2 5 4 3 3 MOSP W=4U L=2U AS=16P AD=16P MRS 5 7 4 0 MOSN W=4U L=2U AS=16P AD=16P * .OP .TRAN 0.01NS 40NS UIC .IC V(1)=1.5 V(2)=0 V(3)=3 V(4)=1.7 V(5)=1.7 V(6)=0 V(7)=3 .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(1) V(2) V(3) V(4) V(5) V(6) V(7) .END vPC 3.0V vWL BL 2.0V D 1.0V BL D 0V Time 0s 8-8 10ns 20ns 30ns 40ns 8.21 +3.3 V 10 1 Each inverter will have vI = v O . vO vI 5 1 Equating inverter drain currents : ⎛100x10-6 ⎞⎛ 5 ⎞ ⎛ 40x10-6 ⎞⎛ 10 ⎞ 2 2 − 0.7 = v ⎟⎜ ⎟( I ⎟⎜ ⎟(3.3 − v I − 0.7) ⎜ ⎜ ) 2 ⎠⎝ 1 ⎠ ⎝ ⎝ 2 ⎠⎝ 1 ⎠ → vO = vI = 1.597 V Sense amp current = 2iDS = 402 µA P = 1024(3.3V)(402 µA)= 1.36 W 8.22 V G C C C C DG BL GS 500 fF BL 500 fF The precharge transistor is operating in the linear region with VDS = 0 1 CGS = Cox" WL + CGSOW 2 −14 1 3.9 8.854x10 F / cm CGS = 10−3 cm 10−4 cm + 4x10−11 F / cm 10−3 cm = 48.6 fF 2 2x10−6 cm 1 ∆VG -3 sC BL ∆VG (s) → ∆V = = = 0.266 V ∆V(s) = 1 1 C BL 500 + +1 +1 CGS sCGS sC BL 48.6 ( ) ( )( )( )( ) This value provides a good estimate of the drop observed in Fig. 8.25. 8-9 8.23 The precharge transistor is operating in the linear region with VDS = 0 1 CGS = Cox" WL + CGSOW 2 −14 1 3.9 8.854x10 F / cm CGS = 10−3 cm 10−4 cm + 4x10−11 F / cm 10−3 cm = 48.6 fF −6 2 2x10 cm Using CBL = 500 fF as in the previous problem, ( ∆V(s) = ) ( 1 sC BL 1 1 + sCGS sC BL )( ∆VG (s)→ ∆V = )( )( ) ∆VG 3 = = 0.266 V C BL 500 +1 +1 48.6 CGS This value provides a good estimate of the observed change in Fig. 8.29. The source - substrate diode will clamp the voltage to ∆V ≤ 0.7 V. 8.24 The bitline will charge to an initial voltage of VBL = 3 - VTN ( ) VTN = 0.7 + 0.5 3 − VTN + 0.6 − 0.6 → VTN = 1.10V | VBL = 1.90V The initial charge QI on C BL : QI = 10−12 F (1.9V )= 1.9 pC After charge sharing : VBL = 1.9 pC = 1.81V. The voltage will be restored to 1.90V 1.05 pF by the transistor. The total charge delivered through the transistor is 9.45x10−14 C ∆Q = 0.09V (1.05 pF )= 0.0945 pC | ∆vO = = 0.945 V 10−13 F 0.945 This sense amplifier provides a voltage gain of AV = = 10.5 0.09 8.25 *PROBLEM 8.24 Charge Transfer Sense Amplifier VSW 5 0 DC 0 PULSE(0 3 2NS .5NS .5NS 100NS) VGG 3 0 DC 3 CL 2 0 100FF CBL 4 0 1PF CC 6 0 50FF M1 2 3 4 0 MOSN W=100U L=2U M2 4 5 6 0 MOSN W=8U L=2U .IC V(2)=3 V(4)=1.9 .TRAN 0.02NS 100NS UIC .MODEL MOSN NMOS KP=25U VTO=0.7 GAMMA=0.5 PHI=0.6 .PROBE V(2) V(3) V(4) V(5) V(6) .END 8-10 3.0V vSW vO 2.0V vBL 1.0V 0V Time 0s 20ns 40ns 60ns 80ns 100ns 8-11 8.26 *PROBLEM 8.26 - Cross-Coupled Latch VDD 1 0 DC 3.3 MN1 3 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MP1 3 2 1 1 MOSP W=2U L=1U AS=16P AD=16P MN2 2 3 0 0 MOSN W=2U L=1U AS=16P AD=16P MP2 2 3 1 1 MOSP W=2U L=1U AS=16P AD=16P CBL1 3 0 1PF CBL2 2 0 1PF .IC V(3)=1V V(2)=1.25V V(1)=5 .OP .TRAN 0.05N 50N UIC .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PRINT TRAN V(2) V(3) .PROBE V(2) V(3) .END 4.0 3.0 2.0 1.0 0 0s Time 5ns V2(CBL1) V2(CBL2) 10ns 15ns 20ns Time 8-12 25ns 30ns 35ns 40ns 8.27 *PROBLEM 8.27 - Cross-Coupled Latch VDD 1 0 DC 3 VSW 4 0 DC 0 PULSE(3 0 5NS 1NS 1NS 100NS) MPC 3 4 2 0 MOSN W=20U L=2U AS=80P AD=80P MN1 3 2 0 0 MOSN W=4U L=2U AS=16P AD=16P MP1 3 2 1 1 MOSP W=8U L=2U AS=32P AD=32P MN2 2 3 0 0 MOSN W=4U L=2U AS=16P AD=16P *MN2 2 3 0 0 MOSN W=4.4U L=2U AS=17.6P AD=17.6P MP2 2 3 1 1 MOSP W=8U L=2U AS=32P AD=32P CBL1 3 0 400FF CBL2 2 0 400FF .OP .TRAN 0.05N 50N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(4) .END 3.0V vPC 2.0V D1 and D 2 1.0V 0V Time 0s 10ns 20ns 30ns 40ns 50ns The latch is perfectly balanced in Part (a) and the voltage levels remain symmetrical even after the PC transistor turns off. This would not happen in the real case because of small asymmetries and noise in the latch. Even a small capacitive imbalance will cause the latch to assume a preferred state. Try setting CBL2 = 425 fF in Part (a) for example. The asymmetry in the latch in Part (b) causes it to switch to a preferred state. 8-13 8.28 *PROBLEM 8.28 - Clocked NMOS Sense Amplifier VPC 2 0 DC 0 PULSE(3 0 1NS .5NS .5NS 250NS) VWL 6 0 DC 0 PULSE(0 3 2NS .5NS .5NS 250NS) VLC 9 0 DC 0 PULSE(0 3 3NS .5NS .5NS 250NS) VDD 3 0 DC 3 CBL1 5 0 2PF CBL2 4 0 2PF *Storage Cell MA1 5 6 1 0 MOSN W=2U L=2U AS=8P AD=8P CC 1 0 100FF *Dummy Cell MA2 4 6 7 0 MOSN W=2U L=2U AS=8P AD=8P CD 7 0 50FF *Sense Amplifier MPC 5 2 4 0 MOSN W=10U L=2U AS=40P AD=40P ML1 3 2 4 0 MOSN W=10U L=2U AS=40P AD=40P ML2 3 2 5 0 MOSN W=10U L=2U AS=40P AD=40P MS1 5 4 8 0 MOSN W=50U L=2U AS=200P AD=200P MS2 4 5 8 0 MOSN W=50U L=2U AS=200P AD=200P MLC 8 9 0 0 MOSN W=50U L=2U AS=200P AD=200P * .OP .TRAN 0.01NS 250NS .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .PROBE V(1) V(2) V(3) V(4) V(5) V(6) V(7) V(8) V(9) .END 3.0V 2.0V 1.0V 0V Time 0s 8-14 50ns 100ns 125ns With only a 3 V power supply, the maximum bit-line differential is only 1.14 V which is achieved in 120 ns. (This is relatively slow due to the discharge of large bitline capacitances and the relatively large threshold voltage of the NMOS transistors.) 8-15 8.29 *PROBLEM 8.29 - Clocked NMOS Sense Amplifier VPC 2 0 DC 0 PULSE(5 0 1NS .5NS .5NS 250NS) VWL 6 0 DC 0 PULSE(0 5 2NS .5NS .5NS 250NS) VLC 9 0 DC 0 PULSE(0 5 3NS .5NS .5NS 250NS) VDD 3 0 DC 5 CBL1 5 0 2PF CBL2 4 0 2PF *Storage Cell MA1 5 6 1 0 MOSN W=2U L=2U AS=8P AD=8P CC 1 0 100FF *Dummy Cell MA2 4 6 7 0 MOSN W=2U L=2U AS=8P AD=8P CD 7 0 50FF *Sense Amplifier MPC 5 2 4 0 MOSN W=10U L=2U AS=40P AD=40P ML1 3 2 4 0 MOSN W=10U L=2U AS=40P AD=40P ML2 3 2 5 0 MOSN W=10U L=2U AS=40P AD=40P MS1 5 4 8 0 MOSN W=50U L=2U AS=200P AD=200P MS2 4 5 8 0 MOSN W=50U L=2U AS=200P AD=200P MLC 8 9 0 0 MOSN W=50U L=2U AS=200P AD=200P * .OP .TRAN 0.01NS 250NS .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .PROBE V(1) V(2) V(3) V(4) V(5) V(6) V(7) V(8) V(9) .END 6.0V 4.0V 2.0V 0V Time 0s 5ns 10ns 15ns 20ns 25ns 30ns With the 5 V power supply, the maximum bit-line differential is 1.75 V. A 1.5 V differential is achieved in approximately 15 ns, which is much faster than the 3 V case. 8.30 8-16 *PROBLEM 8.30 - Cascaded Inverter Pair VDD 1 0 DC 3 VI 2 0 DC 0 MN1 3 2 0 0 MOSN W=2U L=1U AS=16P AD=16P MP1 3 2 1 1 MOSP W=2U L=1U AS=16P AD=16P MN2 4 3 0 0 MOSN W=2U L=1U AS=16P AD=16P MP2 4 3 1 1 MOSP W=2U L=1U AS=16P AD=16P .OP .DC VI 0 3 0.001 .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(2) V(3) V(4) .END 3.0V 2.0V 1.0V vO 0V 0V 0.5V 1.0V 1.5V 2.0V 2.5V 3.0V Results: 0 V, 1.429 V, 3 V 8.31 (a) The array requires: (12 transistors/row) 212 rows + (1 load transistor/row) 212 rows ( ) ( ) ( ) = 13 212 = 53,248 transistors. The 24 inverters require an additional 48 transistors. N = 53,296 transistors | (b) The number is the same. 8-17 8.32 (a) NMOS Pass Transistor Tree : 2 x 20 + 21 + 22 + 23 + 2 4 + 25 + 26 = 254 Transistors ( ) 2 logic inverters per level = 14 inverters = 28 transistors. Total = 282 Transistors (b) An estimate : 128 data bits requires 128 7 - input gates for data selectors; 1 - 128 input NOR gate; 14 address bit inverters Total = 128(8)+ 1(129)+ 14(2) = 1181 transistors without looking closely at the logic detail. A number of additional inverters may be needed, and the 128 input gate can likely be replaced with a smaller NOR tree. 8.33 A0 Clock A1 A2 Clock V DD 0 V DD 1 V DD 2 V DD 3 V DD 4 V DD 5 V DD 6 V DD 7 NMOS Transistor 8-18 8.34 (a) The output of the first NMOS transistor will be [ )] ( V1 = 5 − VTN = 5 − 0.75 + 0.55 V1 + 0.6 − 0.6 → V1 = 3.55V | VTN = 1.45V The output of the other gates reaches this same value. All three nodes = 3.55V. (b) The node voltages will all be + 5 V. 8.35 Charge sharing occurs. Assuming C2 and C3 are discharged (the worst case) (a) V B = (c) V B = C1VDD + C2 (0) 2C2VDD 2 2 = VDD | Node B drops to VDD . C1 + C2 2C2 + C2 3 3 ⎛2 ⎞ 2 V 3C ⎜ ⎟ 2 DD C + C V + C 0 ( 1 2 )3 DD 3 ( ) V 1 ⎝3 ⎠ V = = = DD | Node B drops to VDD . b () B 2C2 + C2 + C2 C1 + C2 + C3 2 2 = C1VDD RC2VDD R C = = VDD ≥ VIH where R = 1 C1 + C2 + C3 RC2 + C2 + C2 R + 2 C2 R(VDD − VIH ) ≥ 2VIH or R ≥ 2VIH VDD − VIH Using VDD = 5V , VTN = 0.7V , VTP = −0.7V in Eq. (7.9) : VIH = 5(5)+ 3(0.7)+ 5(−0.7) 8 = 2.95V | R ≥ 2(2.95) 2VIH = = 2.88 | C1 ≥ 2.88C2 VDD − VIH 2.05 8.36 Z = A0 + A1 + A2 VDD Clock A0 A1 A Z 2 C1 8-19 8.37 B7 B6 B5 B4 B3 B2 B1 B0 W0 W1 W2 1 0 1 0 1 1 1 0 0 1 0 0 0 0 0 0 1 1 0 1 0 0 0 0 W3 W4 0 0 0 0 1 0 0 0 1 1 0 1 1 1 1 0 W5 0 1 0 0 0 0 0 0 8.38 VDD Clock W L W 5 W L 4 W L W L *PROBLEM 8.38 - Simplified ROM Cross-Section VCLK 1 0 DC 0 PULSE(0 5 2.5NS 1NS 1NS 25NS) VW5 3 0 DC 0 PULSE(0 5 4.5NS 1NS 1NS 25NS) VDD 5 0 DC 5 MPC 4 1 5 5 MOSP W=4U L=2U AS=16P AD=16P MNC 2 1 0 0 MOSN W=4U L=2U AS=16P AD=16P MW5 4 3 2 0 MOSN W=4U L=2U AS=16P AD=16P MWW 4 0 2 0 MOSN W=16U L=2U AS=64P AD=64P .OP .TRAN 0.01NS 15NS .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(1) V(2) V(3) V(4) V(5) .END 8-20 6.0V vO 4.0V vCLK 2.0V vW5 0V Time 0s 2ns 4ns 6ns 8ns 10ns 12ns 8.39 W1 W2 B5 0 1 B4 0 0 B3 1 0 B2 0 1 B1 1 0 B0 0 1 W3 0 1 1 1 0 1 B2 B1 B0 W0 W1 W2 1 1 1 0 1 0 1 0 1 W3 0 1 0 8.40 Note that the input lines are active low. 8-21 8.41 +5 V 4 1 4 1 (2.64V) Q Q 0.7V M +5 V R 2 1 2 1 OFF Regenerative switching of the cell will take place when the voltage at Q is pulled low enough by transistor MR that the voltage at Q rises above the NMOS transistor threshold voltage. Equating drain currents for this condition yields the value of VQ . It appears that the NMOS transistor will be in the linear region, and the PMOS transistor will be saturated. ⎛ ⎞⎛ 2 4 x10−5 ⎛ 4 ⎞ 0.7 ⎞ −4 2 For VDD = 5V, ⎜ ⎟(5 − VQ − 0.7) = 10 ⎜ ⎟⎜VQ − 0.7 − ⎟0.7 → VQ = 2.64V which agrees with 2 ⎠ 2 ⎝1⎠ ⎝ 1 ⎠⎝ the assumptions. Now, MR must be large enough to force VQ = 2.64V . MR and the PMOS load transistor are both in the linear region. ⎛ 4 ⎞⎛ ⎛ ⎞ ⎛ ⎛W ⎞ 1.16 2.36 ⎞ 2.64 ⎞ −4 W 4 x10−5 ⎜ ⎟⎜ 5 − 0.7 − 0.7 − ⎟2.36 ≤ 10 ⎜ ⎟ ⎜ 5 − 0.7 − ⎟2.64 → ⎜ ⎟ ≥ 2 ⎠ 2 ⎠ 1 ⎝ 1 ⎠⎝ ⎝ L ⎠R ⎝ ⎝ L ⎠R 8.42 The inputs are active in the low voltage state. V1 low sets the latch and V2 low resets the latch. V1 = S V2 = R . 8-22 8.43 *PROBLEM 8.43 - D-Latch VDD 7 0 DC 2.5 VI 1 0 DC 2.5 VCLK 2 0 DC 0 PULSE(0 2.5 3NS 1NS 1NS 5NS) VNCLK 3 0 DC 0 PULSE(2.5 0 3NS 1NS 1NS 5NS) MTN1 1 2 4 0 MOSN W=2U L=1U AS=16P AD=16P MTP1 1 3 4 7 MOSP W=2U L=1U AS=16P AD=16P MIN1 5 4 0 0 MOSN W=2U L=1U AS=16P AD=16P MIP1 5 4 7 7 MOSP W=2U L=1U AS=16P AD=16P MIN2 6 5 0 0 MOSN W=2U L=1U AS=16P AD=16P MIP2 6 5 7 7 MOSP W=2U L=1U AS=16P AD=16P MTN2 6 3 4 0 MOSN W=2U L=1U AS=16P AD=16P MTP2 6 2 4 7 MOSP W=2U L=1U AS=16P AD=16P .OP .TRAN 0.01N 12N .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 3.0V 2.0V 1.0V 0V -1.0V 0s 1ns 2ns 3ns 4ns 5ns 6ns 7ns 8ns 9ns 10ns 11ns 12ns 8-23 8.44 *PROBLEM 8.44 - Master-Slave Flip-Flop VDD 10 0 DC 5 VI 1 0 DC 5 PWL(0 5 17.4NS 5 17.6NS 0 30NS 0) VCLK 2 0 DC 0 PULSE(0 5 0NS 2.5NS 2.5NS 7.5NS) VNCLK 3 0 DC 0 PULSE(5 0 0NS 2.5NS 2.5NS 7.5NS) MTN1 1 2 4 0 MOSN W=4U L=2U AS=16P AD=16P MTP1 1 3 4 10 MOSP W=4U L=2U AS=16P AD=16P MIN1 5 4 0 0 MOSN W=4U L=2U AS=16P AD=16P MIP1 5 4 10 10 MOSP W=4U L=2U AS=16P AD=16P MIN2 6 5 0 0 MOSN W=4U L=2U AS=16P AD=16P MIP2 6 5 10 10 MOSP W=4U L=2U AS=16P AD=16P MTN2 6 3 4 0 MOSN W=4U L=2U AS=16P AD=16P MTP2 6 2 4 10 MOSP W=4U L=2U AS=16P AD=16P * MTN3 6 3 7 0 MOSN W=4U L=2U AS=16P AD=16P MTP3 6 2 7 10 MOSP W=4U L=2U AS=16P AD=16P MIN3 8 7 0 0 MOSN W=4U L=2U AS=16P AD=16P MIP3 8 7 10 10 MOSP W=4U L=2U AS=16P AD=16P MIN4 9 8 0 0 MOSN W=4U L=2U AS=16P AD=16P MIP4 9 8 10 10 MOSP W=4U L=2U AS=16P AD=16P MTN4 9 2 7 0 MOSN W=4U L=2U AS=16P AD=16P MTP4 9 3 7 10 MOSP W=4U L=2U AS=16P AD=16P .IC V(1)=5 V(2)=0 V(3)=5 V(4)=0 V(5)=5 V(6)=0 V(7)=0 + V(8)=5 V(9)=0 V(10)=5 .TRAN 0.05N 20N UIC .MODEL MOSN NMOS KP=5E-5 VTO=0.91 GAMMA=0.99 +LAMBDA=.02 TOX=41.5N +CGSO=330P CGDO=330P CJ=3.9E-4 CJSW=510P .MODEL MOSP PMOS KP=2E-5 VTO=-0.77 GAMMA=0.5 +LAMBDA=.05 TOX=41.5N +CGSO=315P CGDO=315P CJ=2.0E-4 CJSW=180P .PROBE V(1) V(2) V(3) V(4) V(6) V(7) V(9) .END The flip-flop operates normally. Data is transferred to the master following the first clock transition and to the slave after the second clock transition. The maximum rise and fall times are highly dependent upon the position of the data transition edge. It is interesting to experiment with the data delay to see the effect. At some point the flip-flop will fail. 8-24 6.0V Data 4.0V CLK CLK 2.0V Master Data Slave 0V Time 0s 5ns 10ns 15ns 20ns 8-25 CHAPTER 9 9.1 Since VREF = −1.25V , and v I = −1.6V , Q1 is off and Q2 is conducting. vC1 = 0 V and vC 2 = −α F I EE RC ≅ −I EE RC = −(2mA)(350Ω) = −0.700 V 9.2 ⎛ ∆V ⎞ IC 2 0.995α F I EE = exp⎜ BE ⎟ ⇒ ∆VBE = 0.025ln = 0.132V IC1 0.005α F I EE ⎝ VT ⎠ (a) v I = VREF + ∆VBE = −1.25 + 0.132 = −1.12 V v I = VREF + ∆VBE = −1.25 − 0.132 = −1.38 V (b) v I = VREF + ∆VBE = −2.00 + 0.132 = −1.87 V v I = VREF + ∆VBE = −2.00 − 0.132 = −2.13 V 9.3 Since VREF = −2V , and v I = −1.6V , Q2 is off and Q1 is conducting. vC 2 = 0 V and vC1 = −α F I EE RC ≅ −I EE RC = −(2.5mA)(700Ω)= −1.75 V Note that Q1 is beginning to enter the saturation region of operation, but VBC = +0.15 V is not really enough to turn on the collector-base diode. (See Problems 9.5 or 5.61.) 9.4 vI = VREF + 0.3V ⇒ Q1 on; Q2 off. IC1 = α F I EE ≅ I EE = 0.3mA | IC 2 = 0 vC1 = 0 − IC1 (R1 + RC )= −0.3mA(3.33kΩ + 2 kΩ) = −1.60 V vC 2 = 0 − IC1 R1 = −0.3mA(3.33kΩ) = −0.999 V 9-1 9.5 With VBE = 0.7 and VBC = 0.3, the transistor is technically in the saturation region, but calculating the currents using the transport model in Eq. (5.13) yields βF = 0.98 0.2 αF αR = = 49 | β R = = = 0.25 1− α F 1− 0.98 1− α R 1− 0.2 ⎡ ⎛ 0.7 ⎞ ⎛ 0.3 ⎞⎤ 10−15 ⎡ ⎛ 0.3 ⎞ ⎤ iC = 10−15 ⎢exp⎜ ⎟ − exp⎜ ⎟⎥ − ⎟ −1⎥ = 1.446 mA ⎢exp⎜ ⎝ 0.025 ⎠⎦ 0.25 ⎣ ⎝ 0.025 ⎠ ⎦ ⎣ ⎝ 0.025 ⎠ ⎡ ⎛ 0.7 ⎞ ⎛ 0.3 ⎞⎤ 10−15 ⎡ ⎛ 0.7 ⎞ ⎤ iE = 10−15 ⎢exp⎜ − exp ⎟ ⎜ ⎟⎥ + ⎟ −1⎥ = 1.476 mA ⎢exp⎜ ⎝ 0.025 ⎠⎦ 49 ⎣ ⎝ 0.025 ⎠ ⎦ ⎣ ⎝ 0.025 ⎠ 10−15 ⎡ ⎛ 0.7 ⎞ ⎤ 10−15 ⎡ ⎛ 0.3 ⎞ ⎤ iB = ⎟ −1⎥ + ⎟ −1⎥ = 29.52 µA ⎢exp⎜ ⎢exp⎜ 49 ⎣ ⎝ 0.025 ⎠ ⎦ 0.25 ⎣ ⎝ 0.025 ⎠ ⎦ At 0.3 V, the collector-base junction is not heavily forward-biased compared to the baseemitter junction, and IC = 48.99IB ≅ β F IB . The transistor still acts as if it is operating in the forward-active region. 9.6 (a) For Q2 off, VH = 0 V. For Q2 on, IC ≈ IE and −0.2 − 0.7 − (−2) = 100 µA VL ≅ −4000I E = −0.400 V 1.1x10 4 (b) Yes, these voltages are symmetrically positioned above and below VREF, i. e. VREF ± 0.2 V, and the current will be fully switched. See Parts (d) and (e). 0 − 0.7 − (−2) 0.4V = 118 µA R = = 3.39 kΩ (c) For v I = 0, IC ≅ I E = 4 118µA 1.1x10 IE = (d) Q2 is cutoff. Q1 is saturated with VBC = +0.4 V. (e) Q1 is cutoff. Q2 is saturated with VBC = +0.2 V. (f) 0.2 V and 0.4 V are not large enough to heavily saturate Q1 or Q2. Although the transistors are technically operating in the saturation region, the transistors still behave as if they are in the forward-active region. (See problem 10.5). 9-2 9.7 (a) For v −0.2 − 0.7 − (−2) = 100 µA | VL ≅ −4000I E = −0.400 V 1.1x10 4 0 − 0.7 − (−2) 0.4V = 118 µA | R = = 3.39 kΩ For vI = VH = 0V , IC ≅ I E = 4 118µA 1.1x10 ⎛100µA + 118µA ⎞ P = 2V ⎜ ⎟ = 218 µW 2 ⎝ ⎠ R 11kΩ R 4kΩ R 3.39kΩ (b) REE' = 5EE = 5 = 2.20 kΩ | RC1' = 5C1 = 5 = 800 Ω | RC' 2 = 5C2 = 5 = 678 Ω I = VL , I E = 9.8 VH = 0 − VBE = −0.7 V | VL = −(5mA)(200Ω)− 0.7 = −1.70 V VREF = VH + VL = −1.2 V | ∆V = (5mA)(200Ω)= 1.00 V 2 9.9 VH = 0 − VBE = −0.7 V | VL = −(1mA)(600Ω)− 0.7 = −1.30 V VREF = VH + VL = −1.0 V | ∆V = (1mA)(600Ω) = 0.600 V 2 9.10 I EE = 4(0.3mA) = 1.2 mA | I3 = I 4 = 4(0.1mA)= 0.4 mA | RC = 2kΩ = 500Ω 4 9.11 (a) R C = ∆V 0.8V = = 2.67 kΩ | VH = 0 − VBE = −0.7 V | VL = −0.8 − VBE = −1.5 V I EE 0.3mA VH + VL = −1.10 V 2 ⎡ ⎡ ⎛ ∆V ⎞⎤ 0.8 ⎛ 0.8 ⎞⎤ ∆V (b) NM H = NM L = 2 − VT ⎢1+ ln⎜⎝ V −1⎟⎠⎥ = 2 − 0.025V ⎢⎣1+ ln⎜⎝ 0.025 −1⎟⎠⎥⎦ = 0.289 V ⎣ ⎦ T (c) For Q1: VCB = -0.8 - (-0.7) = -0.1 V which represents a slight forward bias, but it is not enough to turn on the diode. For Q2: VCB = -0.8 - (-1.10) = +0.3 V which represents a reverse bias. Both values are satisfactory for operation of the logic gate. VREF = 9-3 9.12 (b) For Q1 on and Q2 off, IC1 = α F I EE ≅ I EE = 0.3mA | IC2 = 0 VL = 0 − IC1 (R1 + RC )− 0.7V = −0.3mA(3.33kΩ + 2kΩ)− 0.7V = −2.30 V VH = 0 − IC1 R1 − 0.7V = −0.3mA(3.33kΩ)− 0.7 = −1.70 V ∆V = VH − VL = 0.600 V VH + VL = −2.0V = VREF | Yes, the input and output voltage levels are 2 compatible with each other and are symmetrically placed around VREF. (c) R1 RC RC Q v Q 3 4 v O2 O1 vI Q 1 Q 2 V REF 0.1 mA 0.1 mA IEE - 5.2 V 9.13 (a) See Prob. 9.12 (b) ∆V = α 0.4V = 267 Ω 1.5mA ≅ −I EE R1 − VBE = −1.5mA(800)− 0.7V = −1.90 V I RC ≅ I EE RC | RC = F EE VH = 0 − α F I EE R1 − VBE VL = 0 − α F I EE (R1 + RC )− VBE ≅ −I EE (R1 + RC )− VBE = −1.5mA(1067)− 0.7V = −2.30 V VREF = 9-4 VH + VL −1.90 − 2.30 = = −2.10 V 2 2 9.14 ∆V = ∆VBE + ∆iB 4 RC | Let the Fanout = N; β F = 30. Then there will be N base currents that must be supplied from emitter - follower transistor Q4 : ∆i E4 = N ∆VBE = VT ln ∆iB 4 = I EE βF + 1 ⎡ ⎤ ⎛ ∆I ⎞ I EE IC 4 + ∆IC 4 I + ∆I E 4 ⎥ = VT ln E 4 = VT ln⎜1+ E 4 ⎟ = 0.025ln⎢1+ N IC 4 IE 4 IE 4 ⎠ ⎝ ⎢⎣ (β F + 1)I E 4 ⎥⎦ ∆i E4 I EE =N 2 βF + 1 (β F + 1) ⎛ 0.3mA ⎞ 0.3mA ⎟+ N ∆V = ∆VBE + ∆iB 4 RC = 0.025ln⎜⎜1+ N 2kΩ | ∆V ≤ 0.025 2 ⎟ 31 0.1mA ( ) ⎠ ⎝ (31) ⎛ 3N ⎞ 0.6N 0.025 = 0.025ln⎜1+ ⎟+ 31 ⎠ (31)2 ⎝ | Using MATLAB or HP - Solver : N ≤ 11.01 → N = 11 9.15 ' ' = 8RC1 = 8(1.85kΩ) = 14.8 kΩ | RC2 = 8RC2 = 8(2kΩ)= 16.0 kΩ RC1 ' REE = 8REE = 8(11.7kΩ)= 93.6 kΩ | R' = 8R = 8(42kΩ)= 336 kΩ 9.16 RC1 1850Ω R 2000Ω ' = = 231 Ω | RC2 = C2 = = 250 Ω 8 8 8 8 R 11.7kΩ R 42kΩ ' REE = EE = = 1.46 kΩ | R' = = = 5.25 kΩ 8 8 8 8 ' (b) RC1 = 5RC1 = 5(1.85kΩ) = 9.25 kΩ | RC' 2 = 5RC 2 = 5(2kΩ)= 10.0 kΩ ' = (a) RC1 ' REE = 5REE = 5(11.7kΩ) = 58.5 kΩ | R' = 5R = 5(42kΩ)= 210 kΩ 9-5 9.17 ∆V = α F I EE RC ≅ I EE RC = 0.2mA(2kΩ) = 0.400 V VH = 0 − α F I EE R1 − VBE ≅ −I EE R1 − VBE = −0.2mA(2kΩ)− 0.7V = −1.10 V VL = 0 − α F I EE (R1 + RC )− VBE ≅ −I EE (R1 + RC )− VBE = −0.2mA(4kΩ)− 0.7V = −1.50 V VH + VL −1.10 −1.50 = = −1.30 V 2 2 ⎡ ⎡ ⎛ ∆V ⎞⎤ 0.4 ⎛ 0.4 ⎞⎤ ∆V − VT ⎢1+ ln⎜ −1⎟⎥ = − 0.025V ⎢1+ ln⎜ −1⎟⎥ = 0.107 V NM L = NM H = 2 ⎝ 0.025 ⎠⎦ ⎠⎦ 2 ⎝ VT ⎣ ⎣ VREF = IE3 + IE 4 = [V − (−2)]+ [V − (−2)] = (4 −1.10 −1.50)V = 28.0 µA H L 50kΩ R P = 28µA(2V )+ 0.2mA(5.2V )= 1.10 mW 9.18 NM H = ⎡ ⎛ ∆V ⎞⎤ ∆V − VT ⎢1+ ln⎜ −1⎟⎥ | 2 ⎝ VT ⎠⎦ ⎣ 0.1V = ∆V − 0.025V 1+ ln (40∆V −1) 2 [ ] Solving by trial - and - error, HP - Solver, or MATLAB : ∆V = 0.383 V function f=dv15(v) f=4-20*v+1+log(40*v-1); fzero('dv15',0.5) yields ans = 0.3831 9.19 (a) The change in vBE will be neglected : ∆v BE = VT ln 0.8IC = −5.6mV IC V H = 0 − VBE = 0 − 0.7 = −0.7 V - no change VL = 0 − α F IEE RC − VBE ≅ −IEE RC − VBE = −0.3mA(1.2)(2kΩ) − 0.7V = −1.42 V VL has dropped by 0.12V. | ∆V = 0.3mA(1.2)(2kΩ) = 0.72 V ⎡ ⎛ ∆V ⎞⎤ 0.72 ⎡ ⎛ 0.72 ⎞⎤ ∆V − VT ⎢1+ ln⎜ −1⎟⎥ = − 0.025V ⎢1+ ln⎜ −1⎟⎥ = 0.252 V ⎝ 0.025 ⎠⎦ 2 2 ⎣ ⎝ VT ⎠⎦ ⎣ (b) At node A : VH = 0 − VBE = 0 − 0.7 = −0.7 V - no change NM H = NM L = VL = 0 − α F IEE RC − VBE ≅ −IEE RC − VBE = − −1.0 − 0.7 − (−5.2) V (1.2)(2kΩ) − 0.7V = −1.30 V 1.2(11.7kΩ) VL also has not changed! | Similar results hold at node B because the voltages are set by resistor ratios. NM H = NM L = 9-6 ⎡ ⎛ ∆V ⎞⎤ 0.6 ⎡ ⎛ 0.6 ⎞⎤ ∆V − VT ⎢1+ ln⎜ −1⎟⎥ = − 0.025V ⎢1+ ln⎜ −1⎟⎥ = 0.197 V, unchanged ⎝ 0.025 ⎠⎦ 2 ⎣ ⎝ VT ⎠⎦ 2 ⎣ 9.20 (a) V H = −0.7V | ∆V = 0.8V | VL = −0.8 − 0.7 = −1.5V | VREF = VH + VL = −1.1V 2 −1.1− 0.7 − (−5.2) V 0.8V = 11.3 kΩ | RC 2 = = 2.67 kΩ mA 0.3 0.3mA −0.7 − 0.7 − (−5.2) V 0.8V = 0.336mA | RC1 = = 2.38 kΩ I E1 = kΩ 11.3 0.336mA ⎡ ⎞⎤ ⎛ 0.8 0.8 NM = NM = − 0.025V 1+ ln −1 b ⎢ ⎟⎥ = 0.289 V ⎜ () H L 2 ⎝ 0.025 ⎠⎦ ⎣ REE = (c) V CB1 = −0.8 − (−0.7)= −0.1V | VCB2 = −0.8 − (−1.1)= +0.3V The collector - base junction of Q2 is reverse - biased by 0.3 V. Although the collector - base junction of Q1 is forward - biased by 0.1 V, this is not large enough to cause a problem. Therefore the voltages are acceptable. 9.21 NM H = ⎡ ⎛ ∆V ⎞⎤ ∆V − VT ⎢1+ ln⎜ −1⎟⎥ 2 ⎠⎦ ⎝ VT ⎣ For room temperature, VT = 0.025V : 0.1V = For - 55C, VT = 0.0188V : 0.1V = ⎡ ⎛ ∆V ⎞⎤ ∆V − 0.025V ⎢1+ ln⎜ −1⎟⎥ → ∆V = 0.383V 2 ⎝ 0.025 ⎠⎦ ⎣ ⎡ ⎛ ∆V ⎞⎤ ∆V − 0.0188V ⎢1+ ln⎜ −1⎟⎥ → ∆V = 0.346V 2 ⎝ 0.0188 ⎠⎦ ⎣ For + 75C, VT = 0.0300V : 0.1V = ⎡ ⎛ ∆V ⎞⎤ ∆V − 0.0300V ⎢1+ ln⎜ −1⎟⎥ → ∆V = 0.413V 2 ⎝ 0.0300 ⎠⎦ ⎣ ∆V = 0.413 V 9-7 9.22 In the original circuit : VH = −2mA(2kΩ)− 0.7V = −1.1V | ∆V = 2mA(2kΩ)= 0.4V VL = −1.1V − ∆V = −1.5V. VH and VL are symmetrically placed about VREF . −1.3 − 0.7 − (−5.2) V = 16.0 kΩ. R1 and R C2 remain unchanged. 0.2 mA −1.1− 0.7 − (−5.2) V For Q1 on and and Q2 off : I EE = = 0.2125mA 16.0 kΩ VL1 = −(0.2125mA)(2kΩ + RC1)− 0.7V | VL1 = −1.5V → RC1 = 1.77 kΩ. REE = Note that there are only 3 variables (R1 , RC1 and R C2 ) and four voltage levels. Thus we cannot force them all to the desired level. For this design, VH 2 = −(0.2125mA)(2kΩ)− 0.7V = −1.125V rather than the desired -1.10V 9.23 60kΩ (−5.2V )= −3.0V | REQ = 60kΩ 44kΩ = 25.38kΩ 60kΩ + 44kΩ −3.0 − 0.7 − (−5.2) V −3.0 − 0.7 − (−5.2) V = | I EE = β F I BS = β F 25.38 + (β F + 1)30 kΩ 25.38 + (β F + 1)30 kΩ VEQ = I BS For large β F , I EE = −3.0 − 0.7 − (−5.2) V requires VCBS ≥ 0V | VCBS = 50.0 µA | Active region operation 30 kΩ = VREF − VBE2 − VBS = VREF − 0.7V − (−3V ) VREF − 0.7V − (−3V )≥ 0 → VREF ≥ −2.30 V 9.24 The base of QS must not be higher than VL − 0.7 = −0.2mA(4kΩ)− 0.7 − 0.7 = −2.2V Design choice - Choose VB = −3 V. Assume β F = 50. | I B = RE = VB − VEE −3 − (−5.2) = = 10.8 kΩ → RE = 11 kΩ IE 0.204mA Choose I R 2 = 20µA. R2 = I R1 = I R 2 − I B = 16µA. R1 = 9-8 0 − (−3) 20µA = 150 kΩ → R2 = 150 kΩ −3 − (−5.2) 16µA 200µA = 4µA 50 = 138 kΩ → R1 = 136 kΩ 9.25 *PROBLEM 9.25 - ECL INVERTER VTC VIN 2 0 DC -1.3 VREF 4 0 -1.0 VEE 8 0 -5.2 Q1 1 2 3 NBJT Q2 5 4 3 NBJT Q3 0 1 6 NBJT Q4 0 5 7 NBJT REE 3 8 11.7K RC1 0 1 1.85K RC2 0 5 2K R3 6 8 42K R4 7 8 42K .DC VIN -1.3 -0.7 .01 .TEMP -55 25 85 .MODEL NBJT NPN BF=40 BR=0.25 VA=50 .PROBE V(2) V(1) V(5) V(6) V(7) .PRINT DC V(2) V(6) V(7) .END T VT VH VL ∆V VREF VIH VOH VIL VOL NMH NML -55C 0.0188 V -0.846 V -1.40 V 0.554 V -1.00 V -0.918 V -0.865 V -1.08 V -1.38 V 0.053 V 0.300 V +25C 0.0257 V -0.724 V -1.30 V 0.576 V -1.00 V -0.895 V -0.750 V -1.10 V -1.27 V 0.145 V 0.170 V +85C 0.0309 V -0.629 V -1.22 V 0.591 V -1.00 V -0.880 V -0.660 V -1.12 V -1.19 V 0.220 V 0.070 V VIH , VOH , VOL , and VIL were calculated from Eqns. 9.27 - 9.30. With a fixed reference voltage, the noise margins change with temperature and can become zero for a large enough temperature change. 9-9 9.26 RC Q Q A B C D V 2 E 4 REF Y =A+B+C+D+E I EE R -V EE 9.27 R Q C 3 Q B A C D 2 V REF Y=A+B+C+D I EE R -V 9.28 (a ) For Q 4 on, IC 4 = α F I E 4 ≅ I E 4 = EE −0.7 − (−2.5) 840 VL = 1.0V − (2.14mA)(390Ω)− 0.7V = −0.540 V = 2.14 mA For Q4 off, and neglecting the base current in Q5 , VH = 1.0 − 0.7 = +0.300 V (b) For v = 0.3V, IC 2 = α F I E 2 ≅ I E 2 = 0.3 − 0.7 − (−2.5) = 2.50 mA 840 ∆V 0.84V ∆V = 0.30 − (−0.54)= 0.84V | R = = = 336 Ω IC 2 2.50mA 9-10 A 9.29 (a) For Q 4 on, IC 4 = α F I E 4 ≅ I E 4 = −0.7 − (−3.2) 840 VL = 1.3V − (2.98mA)(390Ω)− 0.7V = −0.56 V = 2.98 mA For Q4 off, and neglecting the base current in Q5 , VH ≅ 1.3 − 0.7 = +0.60 V (b) For v = 0.6V , IC 2 = α F I E 2 ≅ I E 2 = 0.6 − 0.7 − (−3.2) = 3.69 mA 840 ∆V 1.16V ∆V = 0.60 − (−0.56)= 1.16V | R = = = 314 Ω IC 2 3.69mA A 9.30 V CC 390 Ω A Q B 2 Q 3 Q Q 4 5 Y=A+B 840 Ω 600 Ω -V EE (a) (b) The NOR output is taken from the collectors of Q2/Q3, and the 390Ω resistor, Q5, and the 600-Ω resistor are removed. 9.31 vOmin = − I EE RL = −(2.5mA)(1.2kΩ) = −3.00 V | I E = I EE + vO 4 − 0.7 = 2.5mA + = 5.25 mA RL 1.2kΩ VBC = 4 − 5 = −1 V , so the transistor is in the forward - active region. IB = IE 5.25mA = = 0.103 mA and IC = β F I B = 5.15 mA. β F + 1 50 + 1 9.32 (a-b) See Problem 9.33 (c) IEE ≥ − (VI − 0.7)V 1kΩ = 3.7V = 3.7 mA 1kΩ 9-11 9.33 Simulation Results from B2SPICE Circuit 9.32-Transient-2 Circuit 9.32-Transient-1 +0.000e+000 (V) +500.000u +1.000m Time (s) +1.500m +0.000e+000 (V) +500.000u +1.000m Time (s) +1.500m +2.000m +2.000m +3.000 +3.000 +2.000 +2.000 +1.000 +1.000 +0.000e+000 +0.000e+000 -1.000 -1.000 -2.000 -2.000 -3.000 -3.000 -4.000 IEE = 4 mA V(1) IEE = 2 mA V(3) V(1) V(3) 9.34 (a) vO = v I − 0.7V = (−1.7 + sin2000πt ) V 2.7V = 0.13 mA with no safety margin. 20kΩ The transistor will cut off at the bottom of the input waveform for IEE = 0.13 mA. (b) vOmin = −2.7V | - IEE RL ≤ −2.7V → IEE ≥ 9.35 Simulation results from B2SPICE Circuit 9.35-Transient-1 (V) +0.000e+000 +500.000u +1.000m Time (s) +1.500m +2.000m +0.000e+000 -500.000m -1.000 -1.500 -2.000 -2.500 -3.000 V(1) V(3) 9.36 (a ) The transistor cuts off for vOmin = -I EE RL = -(0.5mA)(1kΩ) = -0.5V. So vI ≥ -0.5 + 0.7 = +0.2V. For v O > 1.5 V, the transistor enters the saturation region of operation. Therefore : 0.2 V ≤ v I ≤ 1.5 V. (b) v min O = −1.5 − 0.7 = −2.2 V. We need - I EE RL ≤ −2.2V → I EE ≥ 2.2V = 2.2 mA 1kΩ 9.37 vOmin = −10 − 0.7 = −10.7 V . We need - IEE RL ≤ −10.7V → IEE ≥ 9-12 10.7V = 10.7 mA 1kΩ 9.38 Assuming Q1 off and using voltage division, −12 = −15 12 − (−15) 12 + = 60 mA ! 2000 500 IE = 9.39 (a) v min O (b) I ⎛ 4.7kΩ ⎞ = −10 − 0.7 = −10.7 V. We need -15V ⎜ ⎟ ≤ −10.7V ⎝ 4.7kΩ + RE ⎠ (15 −10.7)(4.7kΩ) = 1.89 kΩ RE ≤ 10.7 | IE = −0.7 −0.7 − (−15) + = 7.43 mA | 1890 4700 = E 2000 ⇒ RE = 500 Ω 2000 + RE vI − 0.7 vI − 0.7 − VEE + RE RL (c) I E = −10 − 0.7 −10 − 0.7 − (−15) + = 0 mA 1890 4700 9.40 (a) See the solution to Problem 9.41. (b) v (c) v O = v I − 0.7V = (−2.2 + 1.5sin 2000πt ) V max I IE = = −1.5 + 1.5 = 0V | vOmax = −0.7V | vO vO − VEE + RL RE | I Emax = −0.7 −0.7 − (−6) + = 3.93 mA 1300 4700 −3.7 −3.7 − (−6) + = 0.982 mA 1300 4700 ⎛ 4.7kΩ ⎞ 4.7kΩ(6 − 3.7) = 2920 Ω (e) We need - 6V ⎜⎝ 4.7kΩ + R ⎟⎠ ≤ −3.7V → RE ≤ 3.7 E (d ) v min O = −2.2 −1.5 = −3.7V | I Emin = 9.41 Simulation results from B2SPICE Circuit 9.37-Transient-2 +0.000e+000 +500.000u +1.000m +1.500m Time (s) +2.000m +2.500m +3.000m +0.000e+000 -1.000 -2.000 -3.000 -4.000 V(1) V(3) V(5) 9-13 9.42 The outputs act as a "wired - or" connection. For v I = −0.7V, vO1 = vO 2 = −0.7 V | IE 3 = 0 | IE 4 = 0.1mA + 0.1mA = 0.200 mA For v I = −1.3V, vO1 = vO 2 = −0.7 V | IE 3 = 0.1mA + 0.1mA = 0.200 mA | IE 4 = 0 9.43 Y = A+ B | Z = A+ B 9.44 A Y OR B C NOR D 9.45 For Fig. 9.21, P ≅ 0.5mA(5.2V)= 2.6mW = 2600µW. For 20µW, the power must be reduced by 130X. The currents must be reduced by 130X and the resistors must increase by this factor to keep the logic swing the same : R C = 130(2kΩ)= 260kΩ. Using Eq. (9.54), τ P = 0.69(260kΩ)(2 pF ) = 359 ns - rather slow! 9.46 RC 2kΩ = = 1kΩ | ∆V = 0.3mA(1kΩ) = 0.3V | VH = 0 − 0.7 = −0.7V 2 2 −0.7 −1.0 V = −0.850 V | P ≅ 0.5mA(5.2V )= 2.6mW VL = VH − 0.3V = −1.0V | VREF = 2 τ P = 0.69(1kΩ)(2 pF )= 1.38ns | PDP = 2.6mW (1.38ns)= 3.59 pJ RC' = 9.47 ∆V = 0.15mA(2kΩ) = 0.3V | VH = 0 − 0.7 = −0.7V −0.7 −1.0 V = −0.850 V | P ≅ 0.25mA(5.2V )= 1.30mW 2 τ P = 0.69(2kΩ)(2 pF ) = 2.76ns | PDP = 1.30mW (2.76ns)= 3.59 pJ VL = VH − 0.3V = −1.0V | VREF = 9-14 9.48 ∆V → ∆V = 2 0 − 0.7 − (−1) = 0.6V 2 VL = VH − ∆V = 0 − .6 = −0.600 V. Ignoring the base currents, the average power is ⎡ −1.7 − −3.3 V −1.0 − (−3.3) V ⎤ ( ) ⎢ ⎥ 3.3V = 5.67 mW P≈ + ⎢ ⎥ 1.6kΩ 3.2kΩ ⎣ ⎦ (a) At the outputs : V H ( = 0 V | VREF = VH − 0.7 − ) ( ( ) ) ∆V 0.6 ∆V 0.6 = = 600 Ω | RC1 = = = 505 Ω I EE 2 −1− 0.7 − (−3.3) I EE1 −0.7 − 0.7 − (−3.3) RC 2 = 1600 (b) Y = A + B + C Y = A + B + C (c) 5 versus 6 transistors 1600 9.49 At the outputs : VH = 0 V | VL = VH − ∆V = 0 − .4 = −0.400 V. At the base of QD : VH → VBD = 0 − 0.7 = −0.7V | VL → VBD = −0.4 − 0.7 = −1.10V −0.7 −1.1 = −0.90V | VEE ≤ VREF − 0.7 − 0.6 = −0.9 − 0.7 − 0.6 = −2.20 V 2 −0.9 − (−2.2) V For VEE = −2.20V : RB = = 1.30 kΩ 1 mA −0.9 − 0.7 − (−2.2) + −0.7 − 0.7 − (−2.2) V = 700 Ω RE = 2 1 mA 0.4V 0.4V = 350 Ω | RC 2 = = 467 Ω RC1 = −0.7 − 0.7 − (−2.2) −0.9 − 0.7 − (−2.2) A A 700 700 VREF = [ ][ ] 9-15 9.50 *PROBLEM 9.50 - ECL DELAY VIN 1 0 PULSE(-0.6 0 0 .01NS .01NS 15NS) VB 8 0 -0.6 VREF 6 0 -1.0 VEE 7 0 -3.3 QA 0 1 2 NBJT QB 0 8 2 NBJT QC 0 8 2 NBJT QD 4 2 3 NBJT QE 5 6 3 NBJT RB 2 7 3.2K RE 3 7 1.6K RC1 0 4 505 RC2 0 5 600 .OP .TRAN 0.1N 30N .MODEL NBJT NPN BF=40 BR=0.25 +IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF +RB=100 RC=5 RE=1 .PROBE V(2) V(1) V(4) V(5) V(6) .END 200mV 0V -200mV -400mV -600mV vI Time -800mV 0s 5ns 10ns 15ns Result: τP = 0.95 ns 9-16 20ns 25ns 30ns 9.51 One approach is to scale all the resistor values. To reduce the power from 2.7 mW to 1.0 mW, the resistor values should all be increased a factor of 2.7. RC1 = 2.7(1.85kΩ)= 5.00 kΩ | RC 2 = 2.7(2kΩ)= 5.40 kΩ REE = 2.7(11.7kΩ) = 31.6 kΩ | R = 2.7(42kΩ) = 113 kΩ 9.52 Voltage levels remain unchanged : VREF = −1 V , VH = −0.7 V , VL = −1.3 V , I EE = 0.3 mA −1− 0.7 − (−2) V 0.6V 0.6V = 1 kΩ | RC1 = = = 1 kΩ 0.6mA 0.3 mA −0.7 − 0.7 − (−2) A 1 kΩ −1− (−2) V 0.3 + 0.6 + mA = 0.650mA | P = 0.65mA(2V )= 1.30 mW (-28%) I ≅2 2 10 kΩ Note that this gate will now have quite asymmetrical delays at the two outputs REE = since the two collector resistors differ by a factor of two in value. 9.53 The circuit is the pnp version of the ECL gate in Fig. P9.48. | Y = ABC 9.54 0.7 + 1.3 1mW = +1.0V | I = = 333µA 2 3V (1 + 0.7)+ (0.7 + 0.7) = 1.55V The average voltage at the emitter of QD is 2 (3 −1.55)V = 4.84 kΩ | R = (3 −1)V = 60.1 kΩ | R = 0.6V = 2.23 kΩ RE = B C 0.9(333µA) 0.1(333µA) (3 −1.7)V VL = 0 | VH = VL + ∆V = +0.6V | VREF = 4.84kΩ 9.55 *Problem 9.55(a) - PNP ECL GATE DELAY VI 4 0 PULSE(0.6 0 0 .01NS .01NS 25NS) VB 7 0 DC 0.6 VREF 6 0 DC 1.0 VEE 1 0 DC 3 QA 0 4 3 PBJT QB 0 7 3 PBJT QC 0 7 3 PBJT QD 0 3 2 PBJT QE 5 6 2 PBJT RB 1 3 60.1K RE 1 2 4.84K 9-17 RC 5 0 2.23K .OP .TRAN 0.1N 50N .MODEL PBJT PNP BF=40 BR=0.25 IS=5E-16 +TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF +RB=100 RC=5 RE=1 .PROBE V(4) V(3) V(5) .END 800mV 600mV vI 400mV vO 200mV 0V Time -200mV 0s 10ns 20ns 30ns 40ns 50ns Result: τP = 6.0ns. This delay is dominated by a slow charge up at the base of QD. *Problem 9.55(b) - Prob. 9.4 VIN 1 0 PULSE( -2.3 -1.7 0 .01NS .01NS 15NS) VREF 6 0 -2.0 IEE 2 0 0.0003 Q1 3 1 2 NBJT Q2 4 6 2 NBJT R1 0 5 3.33K RC1 5 3 2K RC2 5 4 2K .OP .TRAN 0.1N 30N .MODEL NBJT NPN BF=40 BR=0.25 IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .PROBE V(1) V(3) V(4) .END Result: τP = 2.4 ns. *Problem 9.55(c) - Fig. P9.16 VIN 1 0 PULSE( -1.5 -1.1 0 .01NS .01NS 15NS) VREF 6 0 DC -1.30 IEE 2 0 DC 0.0002 9-18 Q1 3 1 2 NBJT Q2 4 6 2 NBJT Q3 0 3 7 NBJT Q4 0 4 8 NBJT R1 0 5 2K RC1 5 3 2K RC2 5 4 2K RE1 7 9 50K RE2 8 9 50K VEE 9 0 DC -2 .OP .TRAN 0.1N 30N .MODEL NBJT NPN BF=40 BR=0.25 IS=1E-17 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .PROBE V(1) V(3) V(4) V(7) V(8) .END Result: τP = 3.0 ns. 9.56 Applying the transport model, ⎡ ⎛V ⎞ ⎛ V ⎞⎤ I ⎡ ⎛ V ⎞ ⎤ IC = IS ⎢exp⎜ BE ⎟ − exp⎜ BC ⎟⎥ − S ⎢exp⎜ BC ⎟ − 1⎥ ⎝ VT ⎠⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎣ ⎝ VT ⎠ IS ⎡ ⎛ VBE ⎞ ⎤ IS ⎡ ⎛ VBC ⎞ ⎤ ⎢exp⎜ ⎢exp⎜ ⎟ − 1⎥ + ⎟ − 1⎥ β F ⎣ ⎝ VT ⎠ ⎦ β R ⎣ ⎝ VT ⎠ ⎦ ⎡ ⎛ 0.2 ⎞ ⎛ −4.8 ⎞⎤ 10−15 ⎡ ⎛ −4.8 ⎞ ⎤ −15 IC = 10 ⎢exp⎜ ⎟ − exp⎜ ⎟⎥ − ⎟ − 1⎥ = 2.98 pA ⎢exp⎜ ⎝ 0.025 ⎠⎦ 0.25 ⎣ ⎝ 0.025 ⎠ ⎦ ⎣ ⎝ 0.025 ⎠ IB = IB = 10−15 ⎡ ⎛ 0.2 ⎞ ⎤ 10−15 ⎡ ⎛ −4.8 ⎞ ⎤ ⎟ − 1⎥ + ⎟ − 1⎥ = 74.5 fA ⎢exp⎜ ⎢exp⎜ 40 ⎣ ⎝ 0.025 ⎠ ⎦ 0.25 ⎣ ⎝ 0.025 ⎠ ⎦ Although the transistor is technically in the forward-active region, (and operating with IC = βF IB), it is esentially off - its terminal currents are zero for most practical purposes. 9.57 ⎛ 1 ⎞ For IC = 0, VCESAT = VT ln⎜ ⎟ ⎝αR ⎠ VCESAT 1+ IC (β R + 1)I B ⎛ 1 ⎞ = VT ln⎜ ⎟ ⎝αR ⎠ IC βF I B ⎛ β + 1⎞ ⎛ 1.25 ⎞ = VT ln⎜ R ⎟ = 0.025ln⎜ ⎟ = 0.402 V ⎝ 0.25 ⎠ ⎝ βR ⎠ 1− 9-19 9.58 (a) For the Transport model with VBE = VBC, the transport current iT = 0: I ⎡ ⎛V ⎞ ⎤ I ⎡ ⎛V ⎞ ⎤ I β 40 IC = S ⎢exp⎜ BC ⎟ − 1⎥ and IE = S ⎢exp⎜ BE ⎟ − 1⎥ ⇒ C = F = = 160 β R ⎣ ⎝ VT ⎠ ⎦ β F ⎣ ⎝ VT ⎠ ⎦ IE β R 0.25 (b) v BE = VB − 0.6 | v BC = VB − 0.8 = v BE − 0.2 ⎤ ⎡ v v ⎤ I ⎡ v iE = IS ⎢exp BE − exp BC ⎥ + S ⎢exp BE −1⎥ VT VT ⎦ β F ⎣ VT ⎦ ⎣ ⎡ v v −0.2 ⎤ IS ⎡ v BE ⎤ iE = IS ⎢exp BE − exp BE exp −1⎥ ⎢exp ⎥+ VT VT VT VT ⎦ β F ⎣ ⎦ ⎣ ⎛ ⎡ v ⎤ I ⎡ v ⎤ I ⎡ v ⎤ 1 ⎞⎡ v ⎤ iE ≅ IS ⎢exp BE ⎥ + S ⎢exp BE ⎥ = IS ⎜1+ ⎟⎢exp BE ⎥ = S ⎢exp BE ⎥ VT ⎦ β F ⎣ VT ⎦ VT ⎦ α F ⎣ VT ⎦ ⎣ ⎝ β F ⎠⎣ −−−−− ⎡ v v −0.2 ⎤ IS ⎡ v BE − 0.2 ⎤ iC = IS ⎢exp BE − exp BE exp −1⎥ ⎥ − ⎢exp VT ⎦ β R ⎣ VT VT VT ⎣ ⎦ ⎡ i v ⎤ 40 iC ≅ IS ⎢exp BE ⎥ | C = α F = = 0.976 41 VT ⎦ iE ⎣ i (c ) C = −1 → iB = iE − iC = 2iE | Both junctions will be forward - biased. Neglect iE ⎛ I I v I v v v ⎞ v the -1 terms : S exp BE + S exp BC = 2IS ⎜ exp BE − exp BC ⎟ + 2 S exp BE βF VT β R VT VT VT ⎠ βF VT ⎝ v BE − v BC 1 1 0.25 = 27.2mV = VT ln = 0.025V ln 1 1 2+ 2+ βF 40 2+ βR (v B − v I ) − (v B − 0.8) = 27.7mV 9-20 2+ | v I = 0.773 V 9.59 (a) For the default value of β F = 40, IC = β F I B ⇒ Forward − active region | VBE ≅ VT ln (b) I IC 10−3 A = 0.025V ln −15 = 0.691 V IS 10 A < β F I B ⇒ saturation region; VBE is given by Eqn. 5.45 C VBE ⎛ 1 ⎞ IB + ⎜ ⎟ IC I B + (1− α R )IC ⎝ β R + 1⎠ = VT ln = V ln ⎡ 1 ⎛ 1 ⎞⎤ ⎡1 ⎤ T I S ⎢ + (1− α R )⎥ IS ⎢ + ⎜ ⎟⎥ ⎣β F ⎦ ⎣ β F ⎝ β R + 1⎠⎦ VBE ⎛ 1 ⎞ −3 25x10−6 + ⎜ ⎟10 ⎝ 0.25 + 1⎠ = 0.025V ln = 0.691 V ⎡ ⎛ 1 ⎞⎤ −15 1 10 ⎢ + ⎜ ⎟⎥ ⎣80 ⎝ 0.25 + 1⎠⎦ (c) I C < β F I B ⇒ saturation region | VBE 9.60 βR αR = βR + 1 (a) V CESAT (b) I IC B = = 1 | 2 ⎛ 1 ⎞ −3 10−3 + ⎜ ⎟10 ⎝ 0.25 + 1⎠ = 0.025V ln = 0.710 V ⎡ ⎛ 1 ⎞⎤ −15 1 10 ⎢ + ⎜ ⎟⎥ ⎣40 ⎝ 0.25 + 1⎠⎦ IC 1mA = = 40 I B 25µA ⎛ 1 ⎞ = VT ln⎜ ⎟ ⎝αR ⎠ 1+ IC (β R + 1)I B 1− IC βF I B 1mA = 25 | VCESAT 40µA ⎡ 40 ⎤ ⎢⎛ 3 ⎞ 1+ ⎥ 2 ⎥ = 114 mV = (0.025V )ln ⎢⎜ ⎟ 40 2 ⎝ ⎠ ⎢ 1− ⎥ ⎣ 60 ⎦ ⎡ 25 ⎤ ⎢⎛ 3 ⎞ 1+ ⎥ 2 ⎥ = 88.7 mV = (0.025V )ln ⎢⎜ ⎟ 25 2 ⎢⎝ ⎠ 1− ⎥ ⎣ 60 ⎦ 9-21 9.61 βR 2 1mA I | C = = 40 βR + 1 3 IB 25µA IC ⎡ 40 ⎤ 1+ ⎛ 1 ⎞ (β R + 1)IB ⎢⎛ 3 ⎞ 1+ 3 ⎥ = (0.025V )ln⎢⎜ ⎟ = 117 mV (a) VCESAT = VT ln⎜ ⎟ 40 ⎥ ⎝ ⎠ 2 ⎝ α R ⎠ 1− IC ⎢ 1− ⎥ ⎣ 50 ⎦ β F IB αR = (b) VCESAT 9.62 βR = ⎡ 40 ⎤ ⎢⎛ 3⎞ 1+ 3 ⎥ = (0.025V )ln⎢⎜ ⎟ = 89.5 mV 40 ⎥ ⎝ ⎠ 2 ⎢ 1− ⎥ ⎣ 100 ⎦ 0.25 = 0.2 β R + 1 1.25 ⎞ ⎞ ⎛V ⎛V ⎛ 0.2V ⎞ ⎛ 0.1V ⎞ ⎟ = 2980 ⎟ = 54.6 (a) Γ = exp⎜ CESAT ⎟ = exp⎜ (b) Γ = exp⎜ CESAT ⎟ = exp⎜ ⎝ 0.025V ⎠ ⎝ 0.025V ⎠ ⎝ VT ⎠ ⎝ VT ⎠ ⎤ ⎤ ⎡ ⎡ 40 40 ⎡ ⎡ β ⎤ β ⎤ 1+ F ⎥ 1+ F ⎥ ⎢1+ 0.25 2980 ⎥ ⎢1+ 0.25 54.6 ⎥ ⎢ ⎢ I I I I βRΓ ( )⎥ = IC βRΓ ( )⎥ = IC ⎥= C ⎢ ⎥= C ⎢ IB ≥ C ⎢ IB ≥ C ⎢ 1 1 1 1 β F ⎢1− β F ⎢1− ⎥ 37.9 ⎥ 9.25 ⎥ 40 ⎢ 1− ⎥ 40 ⎢ 1− ⎥ ⎢⎣ ⎢ ⎢⎣ α R Γ ⎥⎦ ⎢ ⎥ 0.2(2980) ⎦ 0.2(54.6) ⎥⎦ ⎣ α RΓ ⎦ ⎣ I 1 ⎛ 5 − 0.2 ⎞ I 1 ⎛ 5 − 0.1⎞ IB ≥ C = IB ≥ C = ⎟ = 63.3 µA ⎟ = 265 µA ⎜ ⎜ β FOR 37.9 ⎝ 2kΩ ⎠ β FOR 9.25 ⎝ 2kΩ ⎠ αR = 9.63 αR = = ⎛V ⎞ ⎛ 0.1V ⎞ 0.25 = 0.2 Γ = exp⎜ CESAT ⎟ = exp⎜ ⎟ = 54.6 ⎝ 0.025V ⎠ β R + 1 1.25 ⎝ VT ⎠ βR = ⎡ ⎤ 40 ⎡ β ⎤ 1+ F ⎥ ⎢1+ 0.25 54.6 ⎥ ⎢ I I βRΓ ( )⎥ = IC ⎥= C ⎢ IB ≥ C ⎢ 1 1 β F ⎢1− ⎥ 9.25 ⎥ 40 ⎢ 1− ⎢⎣ ⎢⎣ α R Γ ⎥⎦ 0.2(54.6) ⎥⎦ I 1 ⎛ 5 − 0.1⎞ IB ≥ C = ⎜ ⎟ = 147 µA β FOR 9.25 ⎝ 3.6kΩ ⎠ 9-22 9.64 ⎛ 1 ⎞ ⎛ β + 1⎞ ⎛ 1.25 ⎞ For IC = 0, VCESAT = VT ln⎜ ⎟ = VT ln⎜ R ⎟ = 0.025ln⎜ ⎟ = 40.2 mV ⎝ 0.25 ⎠ ⎝αR ⎠ ⎝ βR ⎠ ⎛ 1 ⎞ ⎛ β + 1⎞ ⎛ 41 ⎞ For IE = 0, VECSAT = VT ln⎜ ⎟ = VT ln⎜ F ⎟ = 0.025ln⎜ ⎟ = 0.617 mV ⎝ 40 ⎠ ⎝αF ⎠ ⎝ βF ⎠ 9.65 αF = τS = βF βF + 1 = ( 40 0.25 βR = 0.976 α R = = = 0.200 β R + 1 1.25 41 ) = 3.40ns 0.976 0.4ns + 0.2(12ns) 1− 0.976(0.2) t S = (3.40ns)ln 2mA − (−0.5mA) 2.5mA − (−0.5mA) 40 iCMAX ≅ 5V = 2.5 mA 2kΩ = 5.07 ns 9.66 V H = VCC = 3.0 V VL = VCESAT = 0.15 VIL = 0.7 − VCESAT = 0.7 − 0.04V = 0.66V VIH ≅ VBESAT 2 = 0.8 V 3 − 0.7 − 0.8 V = 375µA | IB 2 = 1.25IB1 = 469µA v I = 3V : IB1 = kΩ 4 3 − 0.8 − 0.15 V 3 − 0.15 = −513µA | IC 2SAT = A = 1.43mA v I = 0.15V : IIL = − kΩ 4 2000 1.43mA + N (513µA) ≤ 40(469µA) → N ≤ 33.8 → N ≤ 33. 9.67 vI = VH : I = 5 − 0.7 − 0.8 5 − 0.15 + = 4.13mA | P = 5(4.13mA) = 20.6 mW (0.8)4kΩ (0.8)2kΩ vI = VL : I = 5 − 0.8 − 0.15 = 0.844mA | P = 5(0.844mA)= 4.22 mW (1.2)4kΩ Pmax = 20.6 mW | Pmin = 4.22 mW 9-23 9.68 ⎛ 1 ⎞ Using Eqs. 9.44 and 9.47 : VCC − iC RC = VT ln⎜ ⎟ ⎝αR ⎠ 1+ iC 1.25(1.09mA) ⎛1⎞ 5 − 2000iC = 0.025ln⎜ ⎟ ⎝ .2 ⎠ 1− iC 40(1.09mA) 1+ iC (β R + 1)iB 1− iC β F iB → iC = 2.4659 mA vCESAT = 5 − 2000iC = 0.0682V 9.69 V H = 2.5 V | VL = VCESAT = 0.15 V VIL = 0.7 − VCESAT = 0.55V | VOL ≅ VL = 0.15V VIH ≅ VBESAT 2 = 0.8 V | VOH ≅ V H = 2.5 V NM L = 0.55 − 0.15 = 0.40 V NM H = 2.5 − 0.8 = 1.7 V 9.70 For vI = VH , we require VCC = VBE2SAT + VBC1 + I B1 RB = 0.8 + 0.7 + ∆V = 1.5V + ∆V where ∆V is the voltage across the base resistor. ∆V must be large enough to absorb VBE process variations and to establish the base current. 0.5 V should be sufficient. Thus VCC = 2.0 V or more is acceptable. 9.71 The VTC transitions are set by the values of vBE and vBESAT and are not changed by the power supply voltage. (b) VIL = 0.66 V and VIH = 0.80 V. But VOH ≅ VH = 3 V and VOL ≅ VL = 0.15 V. (c) NMH = 3 - 0.8 = 2.2 V | NML = 0.66-0.15 = 0.51 V. 9.72 We need to reduce the currents by a factor of 11.2. Thus, RB = 11.2 (4kΩ) = 44.8 kΩ and RC = 11.2 (2kΩ) = 22.4 kΩ 9.73 (a) *Problem 9.73 - Prototype TTL Inverter +Delay VI 1 0 DC 0 PWL(0 0 0.2N 5 25N 5 25.2N 0 +50N 0) VCC 5 0 DC 5 Q1 3 2 1 NBJT Q2 4 3 0 NBJT RB 5 2 4K RC 5 4 2K *RB 5 2 45.2K 9-24 *RC 5 4 22.6K .OP .TRAN .1N 80N .MODEL NBJT NPN BF=40 BR=0.25 +IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF +RB=100 RC=5 RE=1 .PROBE V(1) V(2) V(3) V(4) .END 6.0V vI 4.0V 2.0V vO 0V Time (a) -2.0V 0s 20ns Results: (a) τP = 2.9 ns 40ns 60ns 80ns (b) τP = 15.8 ns. 9.74 (a) VH = 5V | VL = VCE2SAT = 0.15V 5 − 0.15 − 0.6 = −1.06 mA 4000 = −I S ≅ 0 where IS is the diode saturation current. vI = VL = 0.15V , I IN = − vI = VH = 5V , I IN 5 − 0.8 − 0.6 5 - 0.15 (b) I = 4000 = 0.90mA; 2000 + N (1.06mA)≤ 40(0.9mA); N ≤ 31. (c) -1.06 mA compared to -1.01 mA and 0 mA compared to 0.22 mA. B 9.75 If we assume that the diode on-voltage is 0.7 V to match the base-emitter voltage of the BJT, then the VTC will be the same as that in Fig. 9.35. Both VTCs will be the same. 9-25 9.76 *Figure 9.76 - Prototype TTL Inverter VTC's VI 1 0 DC 0 VCC 5 0 DC 5 *DTL D1A 6 1 D1 D2A 6 7 D1 RBA 5 6 4K RCA 5 8 2K Q2A 8 7 0 NBJT *TTL Q1B 3 2 1 NBJT Q2B 4 3 0 NBJT RBB 5 2 4K RCB 5 4 2K .DC VI 0 5 .01 .MODEL NBJT NPN BF=40 BR=0.25 IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .MODEL D1 D IS=5E-16 TT=0.15NS CJO=1PF .PROBE V(1) V(2) V(3) V(4) V(6) V(7) V(8) .END 5.0V 4.0V vO 3.0V 2.0V 1.0V 0V 0V 1.0V 2.0V 3.0V 4.0V 5.0V The TTL transition is sharper (more abrupt) and is shifted by approximately 50 mV. 9.77 *Figure 9.77 - Prototype Inverter Delays VI 1 0 DC 0 PWL(0 0 0.2N 5 25N 5 25.2N 0 5 50N 0) VCC 5 0 DC 5 *DTL D1A 6 1 D1 D2A 6 7 D1 RBA 5 6 4K RCA 5 8 2K Q2A 8 7 0 NBJT *TTL Q1B 3 2 1 NBJT Q2B 4 3 0 NBJT RBB 5 2 4K RCB 5 4 2K .OP .TRAN 0.1N 100N .MODEL NBJT NPN BF=40 BR=0.25 IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .MODEL D1 D IS=5E-16 TT=0.15NS CJO=1PF 9-26 vI .PROBE V(1) V(2) V(3) V(4) V(6) V(7) V(8) .END 6.0V vI 4.0V vO TTL 2.0V vO DTL 0V Time -2.0V 0s 20ns 40ns 60ns 80ns 100ns The fall time of the output of the TTL gate is somewhat slower than the DTL gate since transistor Q1 must come out of saturation. However, the rise time of the DTL gate is extremely slow because there is no reverse base current to remove the charge from the transistor base. 9.78 *Figure 9.78 - DTL Inverter Delays VI 1 0 DC 0 PWL(0 0 0.2N 5 25N 5 25.2N 0 50N 0) VCC 5 0 DC 5 *DTLA D1A 6 1 D1 D2A 6 7 D1 RBA 5 6 4K RCA 5 8 2K Q2A 8 7 0 NBJT *DTL-B D1B 2 1 D1 D2B 2 3 D1 Q2B 4 3 0 NBJT RBB 5 2 4K RCB 5 4 2K RB1 3 0 1K .OP .TRAN 0.1N 100N .MODEL NBJT NPN BF=40 BR=0.25 IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .MODEL D1 D IS=5E-16 TT=0.15NS CJO=1PF .PROBE V(1) V(2) V(3) V(4) V(6) V(7) V(8) .END 9-27 ©R. C. Jaeger - February 7, 2007 6.0V vO (b) 4.0V vI 2.0V vO (a) 0V Time -2.0V 0s 20ns 40ns 60ns 80ns 100ns Without the 1-kΩ resistor, the rise time of the DTL gate is extremely slow because there is no reverse base current to remove the charge from the transistor base. The resistor provides an initial reverse base current of -0.7 mA to turn off the transistor and significantly reduces the rise time and propagation delay. 9.79 See problem 9.80. 9.80 *Figure 9.79 - Inverter VTC VI 1 0 DC 0 VCC 6 0 DC 3.3 Q1 3 2 1 NBJT Q2 5 3 4 NBJT Q3 5 4 0 NBJT R1 6 2 4K R2 6 5 2K R3 4 0 3K .OP .DC VI 0 3.3 0.01 .MODEL NBJT NPN BF=40 BR=0.25 IS=1E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .PROBE V(1) V(2) V(3) V(4) V(5) .END Circuit 9.108-DC Transfer-1 VO (V) +0.00e+000 +500.00m +1.00 +1.50 VI +2.00 +2.50 +3.00 +3.50 +3.00 +2.50 +2.00 +1.50 +1.00 +500.00m +0.00e+000 V(2) V(7) The first break point occurs when the input reaches a voltage large enough to just start turning on Q2, at approximately VCESAT1 + VBE2 = 0.04V + 0.6 V = 0.64V. The second breakpoint begins when the input reaches VCESAT1 + VBE2 +VBE3 = 0.04V + 0.7 + 0.6 V = 1.34V. Note 9-28 that the shallow slope is set by the ratio of R2/R3 = 2/3, and also note that Q3 cannot saturate. From the B2SPICE simulation, VH = 3.3 V, VL ≅ VBE3 + VCESAT2 = 0.82V, VIH = 1.38 V, VOL = 0.84 V, VIL = 1.38 V, VOH = 2.82 V. NMH = 2.82 – 1.38 = 1.54 V. NML = 1.38 - 0.84 = 0.54 V. 9.81 VCC = 5 V 0.875 mA 2k Ω 4kΩ iR N(0.875 mA) vH < 5 V N iC = 0 VL 0.15 V 0.875 mA Q2 Q1 + "Off" 0.19 V - From the analysis in the text, we see that the fanout is limited by the VH condition. 5 − 0.7 − 0.8 V iB1 = = 0.875mA | iE1 = −β R iB1 = −0.875mA kΩ 4 5 − 2000(N )(0.875x10−3 )≥ 1.5 → N ≤ 2 → Fanout = 2 9.82 V CC = 5 V 1.2(4 k Ω) 1.2(2k Ω) 1.2(2k Ω) 1.5 V iB1 + 0.7 V VH iIH = β RiB1 Q1 N + (βR + 1)i B1 Q2 0.15 V + 0.8 V - 9-29 From the analysis in the text, we see that the fanout is limited by the VH condition. 5 − 0.7 − 0.8 V iB1 = = 0.729mA | iE1 = −β R iB1 = −0.25(0.729mA) = 0.182mA 4 (1.2) kΩ 5 − 2000(1.2)(N )(0.182x10−3 )≥ 1.5 → N ≤ 8.01 → Fanout = 8 iB1 = 5 − 0.7 − 0.8 V = 1.09mA | iE1 = −β R iB1 = −0.25(1.09mA) = 0.273mA 4 (0.8) kΩ 5 − 2000(0.8)(N )(0.273x10−3 )≥ 1.5 → N ≤ 8.01 → Fanout = 8 The result is independent of the tolerance if the resistors track each other. Note that Eq. 9.83 also yields N = 8 if more digits are used in the calculation. 9.83 From the analysis in the text, we see that the fanout is limited by the VH condition. iB1 = 5 − 0.7 − 0.8 RB iE1 = −β R iB1 = −0.25iB1 5 − 0.7 − 0.8 5 − 2000(N )(0.25) ≥ 1.5 → RB ≥ 5 kΩ RB 9.84 (a) Q4 is in the forward - active region with I E = (β F + 1)I B 5 − 0.7 − 0.6 = 234 mA 1600 5 − 0.8 − 0.6 5 − 0.6 − 0.15 (b) Q4 saturates; I E = I B + IC = 1600 + 130 = 34.9 mA I E = 101 9.85 (a) PD = 5V (234mA) = 1.17 W (b) PD = 5V (34.9mA) = 0.175 W 9-30 9.86 *Figure 9.86 - TTL Output Current VCC 5 0 DC 5 RB 5 3 1.6K RS 5 4 130 Q1 4 3 2 NBJT D1 2 1 D1 IL 1 0 DC 0 .DC IL 0 30MA 0.01MA .MODEL NBJT NPN BF=40 BR=0.25 IS=5E-16 TF =0.15NS TR=15NS +CJC=0.5PF CJE=.25PF CJS=1.0PF RB=100 RC=5 RE=1 .MODEL D1 D IS=5E-16 .PROBE V(1) V(2) V(3) V(4) .END 5.0V vO 4.0V 3.0V 2.0V iL 1.0V 0A 5mA 10mA 15mA 20mA 25mA 30mA 9-31 9.87 *Problem 9.87 - Modified TTL Inverter VTC VI 1 0 DC 0 VCC 9 0 DC 5 Q1 2 8 1 NBJT Q2 4 3 0 NBJT Q3 6 2 3 NBJT Q4 7 6 5 NBJT D1 5 4 DN RB 9 8 4K RC 9 6 1.6K RS 9 7 130 RL 4 0 100K Q5 10 11 0 NBJT RB5 3 11 3K RC5 3 10 1K .DC VI 0 5 .01 .MODEL NBJT NPN BF=40 BR=0.25 IS=1E-17 TF =0.25NS TR=25NS +CJC=0.6PF CJE=.6PF CJS=1.25PF RB=100 RC=5 RE=1 .MODEL DN D .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 4.0V vO 3.0V 2.0V 1.0V 0V 0V 1.0V 2.0V vI 3.0V 4.0V 5.0V In the modified TTL circuit, Q3 cannot start conducting until its base reaches at least VBE5 + VBE6 = 1.2 V. 9-32 9.88 + 5V 20 k Ω 8k Ω + Q 0.7 V - Q 1 + 3 0.8 V - Q + 5k Ω 2 0.8 V - (a) v I = VH : Q4 off − IB 4 = 0 = IC 4 | Q2 saturated with IC 4 = 0 (5 − 0.7 − 0.8 − 0.8)V = 135 µA | I = −β I = −0.25 135 µA = −33.8 µA IB1 = ( ) E1 R B1 20kΩ IC1 = −169 µA | IC 3 = (5 − 0.15 − 0.8)V 8kΩ = 506 µA IE 3 = 506µA + 169µA = 675 µA | IB 2 = 675µA − (b) v I IB1 = = VL : Q2 ,Q3 off ; Q4 on (5 − 0.8 − 0.15)V 20kΩ 0.8V = 515 µA 5kΩ = 203 µA = IE1 | IC1 = 0 9-33 9.89 See Problem 9.90. 9.90 4.0V *Problem 9.90 - Low Power TTL Inverter VTC versus Temperature VI 1 0 DC 0 VCC 9 0 DC 5 Q1 2 8 1 NBJT Q2 4 3 0 NBJT Q3 6 2 3 NBJT Q4 7 6 5 NBJT D1 5 4 DN RB 9 8 20K RC 9 6 8K RS 9 7 650 RL 4 0 100K RE 3 0 5K .DC VI 0 5 .01 .TEMP -55 25 85 .MODEL NBJT NPN BF=40 BR=0.25 IS=1E17 TF =0.25NS TR=25NS +CJC=0.6PF CJE=.6PF CJS=1.25PF RB=100 RC=5 RE=1 .MODEL DN D .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END vO 3.0V 2.0V -55 o C 1.0V +85 o C 0V 0V 9.91 +5V RC RS 130 Ω 1.6 k Ω Q4 V H = 5 − 0.7 − 0.7 − N x 0.17 mA 9-34 N (IIH ) R βF + 1 C N (0.17mA) (1600) 40 + 1 V H ≥ 2.4V → N ≤ 180 V H = 3.6 − +25 o C 1.0V 2.0V vI 3.0V 4.0V 5.0V 9.92 For small β R , fanout is limited by the vO = VL case (v I = V H ). iB 3 = (β R + 1)iB1 = 1.05 (5 − 0.7 − 0.8 − 0.8)V = 567µA 5kΩ (5 − 0.15 − 0.8)V + 567µA − 0.8V = 1.95mA iB 2 = iE 3 − iR E = 2kΩ 1.25kΩ (5 − 0.8 − 0.15)V = 0.810mA | α = β R = 0.05 = 0.0476 iIL = −iE1 = −iB1 = R 5kΩ 1+ β R 1.05 1 1− ⎛ 0.15V ⎞ 0.0476(403.4 ) Using Eq. 9.61, Γ = exp⎜ = 9.52 ⎟ = 403.4 → β FOR = 20 1 20 ⎝ 0.025V ⎠ 1+ 0.05 403.4 N (0.810mA) ≤ 9.52(1.95mA) → N = 22 9.93 For the vO = VL case, the equations are given in Problem 9.92. For vO = VH, V H = 5 − IB 4 RC − 0.7 − 0.7 ≥ 2.4V ⎛ 5 − 0.7 − 0.8 − 0.8 ⎞ ⎛ 2.7 ⎞ IIH = β R ⎜ ⎟ ⎟ = βR ⎜ ⎝ ⎠ ⎝ 4000 ⎠ 4000 NIIH Nβ R ⎛ 2.7 ⎞ IB 4 = = ⎜ ⎟ β F + 1 β F + 1 ⎝ 4000 ⎠ N≤ 1.2(β F + 1)(4000) 2.7β R (1600) 100 Fanout 80 60 40 20 0 0 1 2 3 4 Inverse Current Gain 5 9-35 function [N,X]=P993 br=0; bf=40; g=exp(.15/.025); for i=1:50 br=br+.1; ar=br/(1+br); ib3=(1+br)*675; ib2=1730+ib3; bfor=40*(1-1/(ar*g))/(1+bf/(br*g)); N1=fix(bfor*ib2/1013); N2=1.2*(bf+1)*4000/(2.7*br*1600); N(i)=min(N1,N2); X(i)=0.1*i; end »[Y,X]=p993; »plot(X,Y) 9.94 +2 V +2 V 2 kΩ + 2kΩ + VH iIN Q1 0.7 V - 2kΩ "Saturated" + 0.8 V 0.8 V Q3 - 0.8 V - - Q2 + Q1 0.15 V (a) VH = 2 − VECSAT 2 = 2 − 0.15 = 1.85 V | VL = VCESAT 3 = 0.15 V (2 − 0.7 − 0.8)V = 62.5 µA (b) iIH : iB 2 ≅ 0 | iIH = 0.25 2kΩ (2 − 0.8 − 0.15)V − (2 − 0.8 − 0.8 − 0.15)V = −650 µA iIL = −iB1 = − 2kΩ 2kΩ (c ) Assume β FOR ≤ 28.3 For the pnp transistor : N (62.5µA) ≤ 28.3 (2 − 0.8 − 0.8 − 0.15)V → N = 56 2kΩ (2 − 0.7 − 0.8)V → N = 13 For the npn transistor : N (650µA) ≤ 28.3(1.25) 2kΩ 9-36 9.95 (a) VL = VCESAT 3 = 0.15 V | VH = 2 − VBE 2 = 2 − 0.7 = 1.3 V ⎛ 2 − 0.8 − 0.15 2 − 0.15 − 0.15 ⎞ = 0.15V : iIL = −(iB1 + iC1 ) = −⎜ + ⎟ = −247 µA ⎝ 10000 ⎠ 12000 ⎛ 2 − 0.7 − 0.8 ⎞ v I = 1.3V : iIL = β R iB1 = 0.25⎜ ⎟ = 12.5 µA ⎝ ⎠ 10 4 2 − 0.8 − 0.15 2 − 0.15 − 0.15 + = 1.875mA (c ) Using β FOR = 28.3 : iL = iB 2 + iC 2 = 6000 1000 ⎛ 2 − 0.7 − 0.8 ⎞ 2 − 0.8 iB 3 = + 1.25⎜ ⎟ = 162.5µA ⎝ 10000 ⎠ 12000 (b) v I 28.3(0.1625 mA) ≥ N (0.247 mA) + 1.875mA → N = 11 9.96 (a) Y = ABC (c ) v I (b) VL = VCESAT 3 = 0.15 V | V H = 3.3 − VBE1 − VD = 3.3 −1.4 = 1.9 V = 1.9V, input diode is off and iIH = 0. v I = 0.15V, iIL = − 2.0V 3.3 − 0.7 − 0.15 = −408 µA 6000 vO 1.5V 1.0V 0.5V vI 0V 0V 1.0V 2.0V 3.0V 4.0V The VTC starts to decrease immediately because Q2 is ready to conduct due to the 0.7-V drop across the input diode. When the input has increased to approximately 0.7 V, Q3 begins to conduct and the output drops rapidly. The VTC is much sloppier than that of the corresponding TTL gate. For this particular circuit VIL = 0 and VIH = 0.8 V. Based upon our definitions, NML = 0. However, the initial slope can be reduced by changing the ratio RC/R2 so that VIL = 0.7 V. 9-37 9.97 (a) If either input A is low or input B is low, VB2 will be low. Q2 will be off, Q3 will be on and Y will be low. Therefore Y = A + B → Y = AB . +5 V +5 V 4kΩ 4 kΩ + 0.8 V +0.3 V 0.15 V Q2 +4.3 V +0.45 V - VB Q1 + 10 k Ω 10 k Ω -5 V 5 kΩ -5 V (b) VH = 5 − IB 5 R2 − VBE 5 ≈ 5 − VBE 5 = 5 − 0.7 = 4.30 V VL = 5 − α F IE 3 R2 − IB 5 R2 − VBE 5 ≈ 5 − IE 3 R2 − VBE 5 +0.7 − 0.7 − (−5) = 1.00 mA | VL = 5 − 0.001(4000) − 0.7 = +0.300 V 5000 ⎛ 5 − 0.7 − VB ⎞ VB − (−5) VB − 0.7 − (−5) 1 + → VB = 1.97V ⎟= (c ) v I = 4.3V : 1.25⎜ ⎝ 4000 ⎠ 10000 5000 41 5 − 0.7 − 1.97 IB1 = = 582 µA | IE1 = −0.25 IB1 = −146 µA | IIH = 146 µA 4000 0.3 + 0.15 − (−5) 5 − 0.8 − 0.3 v I = 0.3V : IB1 = = 975 µA | IC1 = − = −545 µA 10000 4000 IE1 = IB1 + IC1 = 430 µA | IIL = −430 µA IE 3 = 9.98 1.5 V 1kΩ 800 Ω 0.70 V 0.25 V 9-38 1kΩ 800 Ω VH Off Q - 0.45 V + 1.5 V + 0.45 V - Q 1 Off + 0.7 V - 1 (a) VH = VCC = 1.5 V | VL = "VCESAT1" = 0.7 − 0.45 = 0.25 V (b) For v I = 1.5V , the input diode is off, and IIH = 0. 1.5 − 0.45 − 0.25 = 1.00 mA 800 (c ) Note that Q1 operates as if it were in the forward - active region : For v I = 0.25V , IIL = β F IB1 ≥ NIIL + IR 2 9.99 vBE + vD2 − vD1 = vCE ⎛ 1.5 − 0.45 − 0.70 ⎞ 1.5 − 0.25 | 40⎜ → N = 16 ⎟ ≥ N (0.001) + ⎠ ⎝ 800 1000 | For vD2 ≅ vD1 , vCE = v BE = 0.7 V iC = iCC + iD1 | iB = iBB − iD1 | iC = β F iB iCC + iD1 = β F (iBB − iD1) → iD1 = β F iBB − iCC 20(0.25)−1 = mA = 0.191 mA βF + 1 21 iD2 = iBB − iD1 = 0.25 − 0.191 = 0.059 mA | iC = 20iB = 20iD2 = 1.18 mA 9.100 In this circuit as drawn, the collector - base junction of Q1 is bypassed by a Schottky diode. Q1 will be "off" with VBC = +0.45 V . iB1 = 5 − 0.45 − 0.7 = 963 µA | IIN = 0 | iB 2 = iB1 = 963 µA 4000 9.101 4.0V 4.0V vO vI 3.0V 3.0V 2.0V 2.0V 1.0V 1.0V vO Time 0V 0V 1.0V 2.0V vI 3.0V 4.0V 5.0V 0V 0s 5ns 10ns 15ns 20ns 25ns 30ns Result: τP = 3.0 ns *Problem 9.101 - Schottky TTL Inverter VTC VI 1 0 DC 3.5 PWL(0 3.5 0.2N 0.25 15N 0.25 15.2N 3.5 30N 3.5) 9-39 VCC 9 0 DC 5 Q1 2 8 1 NBJT D1 2 8 DS Q2 4 3 0 NBJT D2 3 4 DS Q3 6 2 3 NBJT D3 2 6 DS Q4 7 5 4 NBJT Q5 7 6 5 NBJT D5 6 7 DS RB 9 8 2.8K RC 9 6 900 RS 9 7 50 R5 5 0 3.5K RL 4 0 100K Q6 10 11 0 NBJT D6 11 10 DS R2 3 11 500 R6 3 10 250 .OP .DC VI 0 5 .01 .TRAN .025N 30N .MODEL NBJT NPN BF=40 BR=0.25 IS=1E-17 TF =0.15NS TR=15NS +CJC=1PF CJE=.5PF CJS=1PF RB=100 RC=10 RE=1 .MODEL DS D IS=1E-12 .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 9-40 9.102 0.54 k Ω RC Y C VREF + 0.7 V 0.75 k Ω RE -3 V Y = A + B + C | VH = 0 V | VL = −540IC = −540 VREF − 0.7 − (−3) = −0.72(VREF + 2.3) 750 V H + VL = VREF − 0.7 + 0.4 + 0.7 = VREF + 0.4 2 0 − 0.72(VREF + 2.3) = VREF + 0.4 → VREF = −0.903V | VL = −0.72(−.903 + 2.3) = −1.01 V 2 9.103 RC 3.3 k Ω Y V REF- 0.4V V REF V REF- 0.7V 2.4 k Ω RE -3 V Y = A + B + C | V H = 0 V | VL = VREF − 0.4 0 + (VREF − 0.4 ) V H + VL = VREF | = VREF → VREF = −0.40 V | VL = −0.80V 2 2 9-41 9.104 The circuit can be modeled by a normal BJT with a Schottky diode in parallel with the collector base junction. If iC and iB are defined to be the collector- and base-currents of the BJT, iC + iB = 5 − 0.7 1.075mA = 1.075mA | iC ≅ β F iB → iB = = 26.9 µA | iC = 1.05 mA 4000 40 +5 V i=0 4 kΩ iC iB Q1 9.105 If we assume 50% of the gates are switching (an over estimate), 50W = 2µW /gate | τ P = 1ns | PDP = (2µW )(1ns) = 2 fJ (a) P = 0.5(50x10 6 ) (b) PDP = (0.1mW )(0.1ns) = 10 fJ | The result in Part (a) is off the graph! 9.106 If we assume 50% of the gates are switching (an over estimate), 100W = 1µW /gate | τ P = 0.25ns | PDP = (1µW )(0.25ns) = 0.25 fJ (a) P = 0.5(200x10 6 ) (b) PDP = (0.1mW )(0.1ns) = 10 fJ 9.107 | The result in Part (a) is off the graph! PDP 0.5 pJ = = 1.67 ns P 0.3mW (b) P = PDP (a) PDP = (0.7ns)(40mW ) = 28 pJ | τP = PDP 28 pJ = = 2.8 ns P 10mW (a) τ P = τP = 0.5 pJ = 0.5 mW 1ns 9.109 (b) P = 9-42 PDP τP = 28 pJ = 140 mW 0.2ns 9.110 Results from B2SPICE: VH = 4.48 V, VL = 0.54 V, τPHL = 3.3 ns, τPLH = 4.4 ns. Circuit 9_127-DC Transfer-2 +0.000e+000 (V) +500.000m +1.000 +10.000n +20.000n +1.500 +2.000 +30.000n +40.000n VI +2.500 +3.000 +3.500 +4.000 +4.500 +60.000n +70.000n +80.000n +90.000n +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(3) Circuit 9_127-Transient-2 (V) +0.000e+000 Time (s) +50.000n +100.000n +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(3) 9.111 V M4 B A v M3 DD Q4 vO I B M2 R Q 3 A M1 9-43 9.112 VDD M 4 M 3 B A Q4 vO M2 B B M 6 M A 1 A M7 Q3 M 5 9.113 Results from B2SPICE with R = 4 kΩ: VH = 5 V, VL = 0 V, τPHL = 1.9 ns, τPLH = 4.1 ns. Circuit 9_130-DC Transfer-1 +0.000e+000 (V) +500.000m +1.000 +1.500 +2.000 +10.000n +20.000n +30.000n +40.000n +2.500 VI +3.000 +3.500 +4.000 +4.500 +60.000n +70.000n +80.000n +90.000n +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(3) Circuit 9_130-Transient-1 +0.000e+000 (V) +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(3) 9-44 +50.000n Time (s) +100.000n 9.114 V DD V DD M A 3 A M3 M 4 B Q 4 M4 B Q M2 A M B R 1 A B M A M1 R 2 v 4 vO M 5 M6 O M B 6 M5 A B (a) (b) 9.115 Results from B2SPICE: VH = 4.7 V, VL = 0.34 V, τPHL = 7.0 ns, τPLH = 14 ns. Circuit 9_133-DC Transfer-4 +0.000e+000 (V) +500.000m +1.000 +1.500 +2.000 +10.000n +20.000n +30.000n +40.000n +2.500 VI +3.000 +3.500 +4.000 +4.500 +60.000n +70.000n +80.000n +90.000n +5.000 +4.000 +3.000 +2.000 +1.000 +0.000e+000 V(5) Circuit 9_133-Transient-4 +0.000e+000 (V) +50.000n Time (s) +100.000n +5.000 +4.000 +3.000 +2.000 +1.000 V(5) 9-45 CHAPTER 10 10.1 A/C temperature Automobile coolant temperature gasoline level oil pressure sound intensity inside temperature Battery charge level Battery voltage Fluid level Computer display hue contrast brightness Electrical variables voltage amplitude voltage phase current amplitude current phase power power factor spectrum Fan speed Humidity Lawn mower speed Light intensity Oven temperature Refrigerator temperature Sewing machine speed Stereo volume Stove temperature Time TV picture brightness TV sound level Wind velocity 10.2 (a) 20 log (120) = 41.6 dB | 20 log (60) = 35.6 dB | 20 log (50000) = 94.0 dB 20 log(100000) = 100 dB | 20 log(0.90) = −0.915 dB (b) 20 log (600) = 55.6 dB | 20 log (3000) = 69.5 dB | 20 log (106 ) = 120 dB 20 log(200000) = 106 dB | 20 log(0.95) = −0.446 dB (c) 10 log (2x109 ) = 93.0 dB | 10 log (4x105 ) = 56.0 dB 10 log (6x108 ) = 87.8 dB | 10 log(1010 ) = 100 dB 10.3 (a) 4 vO 2 0 vS -2 -4 0 0.5 1 1.5 2 2.5 3 3.5 4 x 10 -3 10-1 (b) 500 Hz : (c) 500 Hz : (d) 500 Hz : (e) Yes 1∠0 o | 1500 Hz : 0.333∠0 o | 2500 Hz : 0.200∠0 o 2∠30 o | 1500 Hz : 1∠30 o | 2500 Hz : 1∠30 o 2∠30 o | 1500 Hz : 3∠30 o | 2500 Hz : 5∠30 o 10.4 Vs = 0.0025V | PO = 40W | Vo = 2PO RL = 2(40)(8) = 25.3V 25.3 = 10100 | 20 log (10100)= 80.1 dB .0025 0.0025V V 25.3V Is = = 45.45nA | I o = o = = 3.162 A 5kΩ + 50kΩ 8Ω 8Ω 3.162 A Ai = = 6.96 x 10 7 | 20 log 3.48 x 10 7 = 157 dB 45.45nA 40W Ap = = 7.04 x 1011 | 10 log 7.04 x 1011 = 118 dB .0025V (45.45nA) Av = ( ) ( ) 2 10.5 Vs = 0.01V | PO = 20mW | Vo = 2PO RL = 2(.02)(8) = 0.566V 0.566 = 56.6 | 20 log (56.6) = 35.0 dB .01 0.01V V 0.566V = 192nA | Io = o = = 70.8mA Is = 2kΩ + 50kΩ 8Ω 8Ω 70.8mA Ai = = 3.68 x 10 5 | 20 log (3.68 x 10 5 )= 111 dB 192nA 0.02W = 2.08 x 10 7 | 10 log (2.08 x 10 7 )= 73.2 dB Ap = .01V (192nA) 2 Av = 10.6 (a) v Rth v th + - vo = (b) v vo = th = voc = 0.768 2 = 1.09 V ⎛ 0.768 − 0.721⎞ RL v −v v th → Rth = RL th o = 430⎜ ⎟ = 28.0 Ω 0.721 Rth + RL vo ⎠ ⎝ th = voc = 0.760 2 = 1.08 V ⎛ 0.760 − 0.740 ⎞ RL v −v v th → Rth = RL th o = 1040⎜ ⎟ = 28.1 Ω 0.740 Rth + RL vo ⎠ ⎝ (c) 1.09 V and 1.08 V → 9% error and 8% error 10-2 G4 laptop – 1 V, 28 Ω. 10.7 10.8 (a) Vo = 2RL PO = 2(8)(20) = 17.9V Pi = Vi2 12 1V 17.9V = = 25.0µW | I i = = 49.9µA | I o = = 2.24 A 20000Ω + 32Ω 8Ω 2Ri 40066 Av = Vo 17.9V 20W 2.24 A = = 17.9 | AP = = 8.00x105 | Ai = = 4.49x10 4 1V 25µW 49.9µA Vi (b) V = 17.9 V ; recommend ± 20 - V supplies o 10.9 2P R The 24-Ω case represents a good trade off between voltage and current. V = 2PR | I= R (Ω) V (V) I (mA) 8 1.27 158 24 2.19 91.3 1000 14.1 14.1 10.10 In the dc steady state, the internal circuit voltages cannot exceed the power supply limits. (a) +15 V (b) -9 V 10.11 (a) For VB = 0.6V , VO = +8V | Av = Av = 32 dB ∠AV = 180 o dvO dvI = v I =0.6V 12 − 4 = −40 0.5 − 0.7 | VM ≤ 0.100 V for linear operation (b) vI (t )= (0.6 + 0.1sin1000t ) V vO (t )= (8 − 4sin1000t ) V 10-3 10.12 (a) For VB = 0.5V , VO = +12V | dvO is different for positive and negative values of dvI VM sin1000t. Thus, the gain is different for positive and negative signal excursions and the output will always be a distorted sine wave. This is not a useful choice of bias point for the amplifier. (b) For VB = 1.1V , VO = +2V and dvO = 0. The gain is zero for this bias point. dvI Thus this is also not a useful choice of bias point for the amplifier. 10.13 (a) For V B = 0.8V , VO = +3V | Av = dvO dv I = v I =0.8V 4−2 = −10 0.7 − 0.9 Av = 20dB ∠AV = 180 o | VM ≤ 0.100 V for linear operation (b) For V B = 0.2V , VO = +14V | Av = dvO dv I =0 v I =0.8V The output signal will be distorted regardless of the value of VM . 10.14 14 vO 12 10 8 6 4 Time 2 0 0.002 0.004 0.006 0.008 0.01 0.012 0.014 The amplifier is operating in a linear region. vO = 8 - 4 sin 1000t volts There are only two spectral components: 8 V at dc and -4 V at 159 Hz 10-4 10.15 For sin 1000t ≥ 0, vO = 12 − 4 sin 1000t For sin 1000t < 0, vO = 12 −1 sin 1000t 14 vO 12 10 8 Time 6 0 0.002 0.004 0.006 0.008 0.01 0.012 0.014 Using the MATLAB FFT capability with a fundamental frequency of 1000/2 Hz: t=linspace(0,2*pi/1000,1000); y=12-4*sin(1000*t).*(sin(1000*t)>=0)-sin(1000*t).*(sin(1000*t)<0); z=fftshift(fft(y))/1000; yields the following series: v O (t ) = 11.05 − 2.50sin(1000t ) + 0.638cos(2000t ) + 0.127cos(4000t ) + 0.0546cos(6000t )Note: It is worth plotting this function to see if it is correct. The Fourier coefficients may also be calculated directly using MATLAB. For example, for the cosine terms: Define a function: function y=four(t) y=cos(fn*1000*t).*(12-4*sin(1000*t).*(sin(1000*t)>=0)sin(1000*t).*(sin(1000*t)<0)); global fn fn=0; quad('four',0,pi/500)*1000/pi 10.16 vI = 0.004sin 2000πt V | Av = THD = 100 5V = 1250 | Third and fifth harmonics are present. 0.004V 0.252 + 0.102 % = 5.39 % 5 10.17 At the input signal frequency : vi = 0.25sin1200πt V | vo = 4sin1200πt V 4V 0.42 + 0.22 Av = = 16 | Second and third harmonics are present. THD = 100 % = 11.2 % 0.25V 4 10-5 10.18 (a) w=200*pi*linspace(0,0.001,512); v=6+4*sin(w).*(sin(w)>=0)+2*sin(w).*sin(w)<0; s=fft(v)/512; vmag=sqrt(s.*conj(s)); vmag(1:3) ans = 6.6354 1.4985 0.2129 dc component: 6.64 V fundamental: 1.50 V 2nd harmonic: 0.213 V (b) Define m-files for a(n) and b(n) function f=an(t); global n; ftemp=6+(4*sin(2000*pi*t)).*(t<=0.0005)+(2*sin(2000*pi*t)).*(t>0.0005); f=ftemp.*cos(2000*n*pi*t); function f=bn(t); global n; ftemp=6+(4*sin(2000*pi*t)).*(t<=0.0005)+(2*sin(2000*pi*t)).*(t>0.0005); f=ftemp.*sin(2000*n*pi*t); Then n=0; quad(‘an’,0,0.001) Then n=1; quad(‘bn’,0,0.001) ans: 13.27 ans 3.000 etc f = 6.63 + 3sin(2000 t) – 0.4244cos(4000 t) –0.0849cos(8000 t) 10-6 10.19 t=linspace(0,0.002,512); y=max(-1,min(1,1.5*sin(1400*pi*t))); plot(t,y) 1.5 1 0.5 0 -0.5 -1 -1.5 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 x 10-3 w=1400*pi*linspace(0,0.001428571,512); y=max(-1,min(1,1.5*sin(w))); s=fft(y)/512; ymag=sqrt(s.*conj(s)); y2=ymag.*ymag; sumy2=sum(y2)-2*y2(1)-2*y2(2); thd=100*sqrt(sumy2)/(2*y2(2)) thd = 18.3929 % 10.20 g11 = i1 : v1 = 10 4 i1 + 101 i1 (240kΩ) → g11 = 4.124 x 10−8 S = 4.12 x 10−8 S v1 i = 0 2 g12 = g21 = g22 = i1 i2 v1 =0 v2 v1 i2 = 0 : i1 = − v2 i2 i + 240kΩ (i2 + 100i1)→ g12 = −9.90 x 10−3 240kΩ + 10kΩ : v2 = 101i1 (240kΩ) | i1 = g11v1 → g21 = 1.00 : i2 = v1 =0 v2 v v + 2 + 100 2 → g22 = 99.0 Ω 240kΩ 10kΩ 10kΩ i 1 10 k Ω v1 = 0 - 100 i 1 240 k Ω i 2 + + v v 2 - i2 = 0 1 1 - + 10 k Ω 100 i 1 240 k Ω v 2 - 10-7 10.21 g11 = 1 24.25 MΩ g12 = −9.897x10−3 g21 = 0.9996 g22 = 98.97 Ω 10.22 g11 = g21 = g22 = i1 v1 = i2=0 v2 v1 i2=0 v2 i2 v1 = 0 1 = 0.286 mS 2.5kΩ +1kΩ : v 2 = v1 =− v1 = 0 1kΩ = −0.286 2.5kΩ +1kΩ : v 2 = (i 2 − 0.04 v a )60kΩ + i 2 (1kΩ 2.5kΩ) | v a = −i 2 (1kΩ 2.5kΩ) 60 k Ω 0.04 v 2.5 k Ω + i1 i2 1kΩ 2.5kΩ + v1 (−0.04 )(60kΩ) → g21 = −1710 2.5kΩ +1kΩ 2.5kΩ +1kΩ g22 = 1.78 x 10 6 Ω i1 | g12 = a i2 i2 - va v2 1k Ω v1 = 0 + - 10.23 g11 = i1 : v1 = 103 i1 → g11 = 1.00 x 10−3 S v1 i =0 2 g12 = g21 = g22 = i1 i2 v1 =0 v2 v1 i2 =0 v2 i2 : i1 = − i2 → g12 = −1.00 : v2 = v1 + 0.1v1(20kΩ) | v1 = 2001v1 → g21 = 2001 : i2 = v1 =0 v2 → g 22 = 20 kΩ 20kΩ 20 k Ω 20 k Ω 0.1v i1 0.1v 1 i2 i 2 i1 - 10-8 0.1v 1k Ω 1 i =0 2 =0 i2 2 + v1 1 i 1k Ω v1 = 0 i=0 0.1v 1 =0 + v2 - 10.24 g11 = 1 1.000 kΩ g12 = −1.000 g21 = 2001 g22 = 20.00 kΩ 10.25 Rin RL A (a) VO = VS Rin + RS RL + Rout | A = 10 54 20 = 501.2 16 10 6 Av = 3 501.2) = 485.5 | AvdB = 20 log(485.5) = 53.7 dB 6 ( 10 + 10 0.5 + 16 485.5VS IO 16 = 3.041 x 10 7 | A idB = 20 log(3.041 x 10 7 )= 150 dB Ai = = VS IS 10 3 + 10 6 485.5VS VO IO 485.5VS 16 = = 485.5(3.041 x 10 7 ) = 1.478 x 1010 AP = V VS IS VS 3 S 6 10 + 10 A PdB = 10 log(1.478 x 1010 )= 102 dB VO2 5.657 → VO = 5.657 V | VS = = 11.65 mV (b) 1 = 2(16) 485.5 (c) R out and R L see the same current. IO2 1 R = 0.5 = 31.25 mW | PR in 2 16 P = 31.25mW + 67.7 pW = 31.3 mW PR out = IO2 I2 1 RL → O = 2 2 16 ⎛ 0.01165 ⎞ 2 10 6 IS2 = Rin = ⎜ 3 = 67.7 pW ⎟ ⎝10 + 10 6 ⎠ 2 2 P= 10.26 ⎛ 54 ⎞ 16 Rin 1000 RL (a) VO = VS R + R A R + R = VS 1000 + 1000 ⎜⎜10 20 ⎟⎟ 16 + 16 = 125 VS in S L out ⎝ ⎠ VO2 5.66 1= → VO = 5.66V | VS = = 45.3 mV 125 2(16) (b) Since R out and R L have the same current and same value, the power dissipated in R out is 1 W. ⎛ 45.3mV ⎞2 1 The power lost in R in is ⎜ = 0.257µW | PD = 0.257µW + 1.00W = 1.00 W ⎟ ⎝ 2 ⎠ 2(1000) 10-9 10.27 io = 2(0.1W ) 2Po = = 91.3 mA | v = io (28 + 24 )Ω = 4.75 V RL 24Ω iv i2R (91.3mA) (28Ω) = 117 mW PD = o = 217mW | PL = o out = 2 2 2 2 10.28 io = 2(0.1W ) 2Po = = 14.1 mA | v = io (28 + 1000)Ω = 14.5 V RL 1000Ω iv i2R (14.1mA) (28Ω) = 2.78 mW PD = o = 103 mW | PL = o out = 2 2 2 2 10.29 Rin = ∞ | Rout = 0 Ω | vO = AvS = −2000v S | vO = 0.01V (−2000)= −20 V P= VO2 202 12.5W = = 12.5 W | AP = =∞ 2RL 2(16) 0 10.30 77 20 20kΩ 2kΩ A → A = −7805 20kΩ + 1kΩ 2kΩ + 0.1kΩ A = −7800 | AdB = 20 log(7800)= 77.8 dB Av = −10 = −7079 | − 7079 = 10.31 i1 = is RS RS + Rin io = βi1 Rout Rout + RL Ai = β Rout RS Rout + RL RS + Rin Rin = 0 Rout = ∞ 10.32 IO = I S RS Rout β RS + Rin Rout + RL 10.33 | 200 = 300kΩ 200kΩ β → β = 243 200kΩ + 10kΩ 300kΩ + 47kΩ 10−6 A(5000)] 4 [ IO2 125mW = ∞ | P = RL = 10 Ω = 125 mW | AP = =∞ 2 2 0 2 Rin = 0 Ω | Rout 10-10 10.34 VO = VS Rin RL Rin A A Rin + RS Rin + Rout RL + Rout 5000 100 5000 −1200) −1200) = +1.82 x 105 ( ( 5000 + 500 100 + 500 5000 + 1000 5 AvdB = 20 log 1.82 x 10 = 105 dB Av = ( ) ( ) IO 1.82x105VS 1 = = +1.09 x 10 7 | AidB = 20 log 1.36 x 10 7 = 141 dB VS IS 100 6000 5 1.82x10 VS +1.09 x 10 7 I S = +1.98 x 1012 | APdB = 10 log 1.98 x 1012 = 123 dB AP = VS I S Ai = ( ) ( ) 10.35 VO ⎛ VO ⎞ 2 RS + Rin VO IO RL AP = = =⎜ ⎟ VS VS IS V RL ⎝ VS ⎠ S RS + Rin ⎤ ⎡⎛ ⎞ 2 ⎛ VO ⎞ 2 ⎛ R + Rin ⎞ VO RS + Rin ⎥ ⎢ = 10log⎜ ⎟ + 10log⎜ S APdB = 10log ⎜ ⎟ ⎟ RL ⎥⎦ ⎢⎣⎝ VS ⎠ ⎝ VS ⎠ ⎝ RL ⎠ ⎛V ⎞ ⎛ RL ⎞ ⎛ RL ⎞ APdB = 20log⎜ O ⎟ −10log⎜ ⎟ = AvdB −10log⎜ ⎟ ⎝ VS ⎠ ⎝ RS + Rin ⎠ ⎝ RS + Rin ⎠ VO ⎛ I ⎞2 R VO IO IO RL IO L AP = = =⎜ O⎟ VS IS IS (RS + Rin )IS ⎝ IS ⎠ RS + Rin 2 ⎡⎛ ⎞ 2 ⎤ ⎛ IO ⎞ ⎛ RL ⎞ IO RL ⎥ = 10log⎜ ⎟ + 10log⎜ AidB = 10log⎢⎜ ⎟ ⎟ ⎢⎣⎝ IS ⎠ RS + Rin ⎥⎦ ⎝ IS ⎠ ⎝ RS + Rin ⎠ ⎛I ⎞ ⎛ R ⎞ ⎛ R ⎞ L L APdB = 20log⎜ O ⎟ + 10log⎜ ⎟ = AidB + 10log⎜ ⎟ ⎝ IS ⎠ ⎝ RS + Rin ⎠ ⎝ RS + Rin ⎠ Note : APdB = AvdB + AidB 2 10-11 10.36 (a) A (s)= i (s 3x109 s2 2 )( + 51s + 50 s2 + 13000s + 3x10 7 ) = 3x109 s2 (s + 1)(s + 50)(s + 3000)(s + 10000) Zeros : s = 0, s = 0 | Poles : s = -1, s = -50, s = -3000, s = -10000 (b) A (s)= s ( ) 105 s2 + 51s + 50 + 1000s + 50000s + 20000s + 13000s + 3x10 7 Using MATLAB to find the poles: v 5 4 3 2 | Zeros : s = -1, s = -50 Av=[1 1000 50000 20000 13000 3e7]; roots(Av) ans = -947.24 -52.13 -9.170 4.27 + j6.93 4.27 - j6.93 10.37 ⎛ ⎞ ⎜ ⎟ R2 ⎜ 1 ⎟ R2 1.5kΩ Vo | Amid = = = = 0.600 | Amid-dB = −4.44 dB s ⎟ Vs R1 + R2 ⎜ R1 + R2 1kΩ + 1.5kΩ ⎜1+ ⎟ ⎝ ωH ⎠ 1 1 = = 26.5 kHz fH = 2π R1 R2 C 2π 1kΩ 1.5kΩ 0.01µF ( ) ( ) 10.38 ⎛ ⎞ ⎜ ⎟ R2 ⎜ 1 ⎟ R2 100kΩ Vo | Amid = = = = 0.909 | Amid-dB = −0.828 dB s ⎟ Vs R1 + R2 ⎜ R1 + R2 10kΩ + 100kΩ ⎜1+ ⎟ ⎝ ωH ⎠ 1 1 fH = = = 1.75 kHz 2π R1 R2 C 2π 10kΩ 100kΩ 0.01µF ( ) ( ) 10.39 −0.5 (a) Amid ≥ 10 20 = 0.944 | C= ( 1 ) 2π R1 R2 f H (b) R 2 10-12 = R2 ≥ 0.944 → R2 ≥ 9440Ω | Choose R2 = 10 kΩ 560 + R2 ( 1 ) 2π 560Ω 10kΩ 20kHz = 10 kΩ | C = 15.0 nF = 0.015 µF 10.40 Vo R2 ⎛ s ⎞ R2 20kΩ = = = 0.667 | Amid-dB = −3.52 dB ⎜ ⎟ | Amid = Vs R1 + R2 ⎝ s + ω L ⎠ R1 + R2 10kΩ + 20kΩ 1 1 = = 531 Hz 2π (R1 + R2 )C 2π (10kΩ + 20kΩ)0.01µF fL = 10.41 Vo R2 ⎛ s ⎞ R2 78kΩ = = = 0.886 | Amid-dB = −1.05 dB ⎜ ⎟ | Amid = Vs R1 + R2 ⎝ s + ω L ⎠ R1 + R2 10kΩ + 78kΩ 1 1 = = 181 Hz 2π (R1 + R2 )C 2π (10kΩ + 78kΩ)0.01µF fL = 10.42 (a) A mid C= ≥ 10 −0.5 20 R2 ≥ 0.944 → R2 ≥ 5560Ω | Choose R 2 = 7.5 kΩ 330Ω + R2 = 0.944 | 1 1 = = 1.02 nF 2π (R1 + R2 )f L 2π (330Ω + 7500Ω)20kHz (b) R 2 10.43 Av = = 7.5 kΩ | C = 1.0 nF | Checking : f L = 20.3 kHz 2π x 10 7 s (s + 20π )(s + 2π x 10 ) 4 = 1000s | A mid = +1000 = 60 dB ⎛ ⎞ s (s + 20π )⎜⎝1+ 2π x 104 ⎟⎠ 20π 2π x 10 4 = 10 Hz | f H = = 10 kHz | BW = 10kHz −10Hz = 9.99 kHz 2π 2π Bandpass Amplifier fL = 10.44 10 4 s | High - pass Amplifier | A mid = +10 4 = 80 dB s + 200π 200π fL = = 100 Hz | f H = ∞ | BW = ∞ 2π Av = 10.45 2π x 106 = s + 200π 10 4 → Low - pass Amplifier | A mid = +10 4 = 80 dB s 1+ 200π 200π = 100 Hz | BW = 100Hz − 0Hz = 100 Hz f L = 0 Hz | f H = 2π Av = 10-13 10.46 Av (s) = 7 s ωo s2 + s ωo 5 10 s 10 s = 102 2 = Amid 5 14 s + 10 s + 10 s + 105 s + 1014 2 Bandpass Amplifier | Amid = 100 = 40 dB | f o = Q Q + ω 2o 10 ω = 1.592 MHz | Q = o5 = 100 2π 10 7 1.592 MHz = 15.92 kHz | For a high Q circuit : 100 BW = 1.592 MHz −15.92kHz = 1.584 MHz fL ≈ fo − 2 BW fH ≈ fo + = 1.592 MHz + 15.92kHz = 1.600 MHz 2 BW = 10.47 s 2 + 1012 s2 + ω o2 = A | Notch Filter mid ω s2 + 10 4 s + 1012 s2 + s o + ω o2 Q ⎞ ⎛ ω ω s o s o ⎟ ⎜ Q Q Note : Av (s) = −20⎜1− is a bandpass function. ⎟ where ωo 2 2 ⎜⎜ s2 + s ω o + ω o2 ⎟⎟ s + s + ωo Q Q ⎠ ⎝ Av (s) = −20 Amid = −20 = 20 dB but Av = 0 at f o | f o = The width of the null = BW = ω o 10 6 ω = = 159.2 kHz | Q = o4 = 100 2π 2π 10 159.2kHz = 1.592 kHz | For a high Q circuit : 100 BW = 159.2Hz −1.592kHz = 157.6 kHz 2 BW = 159.2Hz + 1.592kHz = 160.8 kHz f H ≈ fo − 2 fL ≈ fo − 10-14 10.48 Av (s) = 4 π 2 x 1014 s2 (s + 20π )(s + 50π )(s + 2π x 10 5 )(s + 2π x 10 6 ) Av (s) = 10 3 s2 ⎛ ⎞⎛ ⎞ s s 1+ ⎟ ⎜ ⎟ (s + 20π )(s + 50π )⎜1+ ⎝ 2π x 10 5 ⎠⎝ 2π x 10 6 ⎠ | Amid = 1000 = 60 dB Zeros : s = 0, s = 0 | Poles : s = -20π , s = -50π , s = -2π x 10 5 , s = -2π x 10 6 10 3 ⎛ ⎞⎛ ⎞ s s 1+ ⎜1+ 5 ⎟⎜ 6⎟ ⎝ 2π x 10 ⎠⎝ 2π x 10 ⎠ Since the two high frequency poles are separated in frequency by a decade, For s >> 50π , Av (s) ≈ 2π x 10 5 = 100 kHz | However, we are not that lucky at low frequencies. fH ≈ 2π 10 3 s2 10 3 ω L2 10 3 For s << 2π x 10 5, Av (s) ≅ | Av ( jω L ) = = 2 2 2 (s + 20π )(s + 50π ) ω 2 + (20π ) ω 2 + (50π ) ( [ ] L ω L4 − (20π ) + (50π ) ω L2 − (20π ) (50π ) = 0 → ω L = ±178 | f L = 2 2 2 2 )( L ) 178 = 28.3 Hz 2π 10-15 10.49 Using MATLAB: n=[2e7*pi 0]; d=[1 (20*pi+2e4*pi) 40e4*pi^2]; bode(n,d) 70 60 Gain dB 50 40 30 20 10 0 10 0 10 1 10 2 10 3 10 4 Frequency (rad/sec) 10 5 10 6 100 50 Phase deg 0 -50 -100 -150 -200 10 0 10 1 10.50 Using MATLAB: 10 2 10 3 10 4 Frequency (rad/sec) 10 5 10 6 n=[1e4 0]; d=[1 200*pi]; bode(n,d) Bode Diagrams 80 70 60 50 40 100 80 60 40 20 0 1 10 10 2 10 Frequency (rad/sec) 10-16 3 10 4 10.51 Using MATLAB: n=[2e6*pi]; d=[1 200*pi]; bode(n,d) Bode Diagrams 80 75 70 65 60 55 0 -20 -40 -60 -80 -100 2 10 10 3 10 4 Frequency (rad/sec) 10.52 Using MATLAB: n=[1e7 0]; d=[1 1e5 1e14]; bode(n,d) 100 Gain dB 50 0 -50 -100 10 6 10 7 Frequency (rad/sec) 10 8 Phase deg 100 50 0 -50 -100 10 6 10 7 Frequency (rad/sec) 10 8 10-17 10.53 Using MATLAB: n=[-20 0 -2e13]; d=[1 1e4 1e12]; bode(n,d) Gain dB 30 20 10 0 10 5 10 6 Frequency (rad/sec) 10 7 10 6 Frequency (rad/sec) 10 Phase deg 200 150 100 10 5 7 10.54 Using MATLAB: n=[4e14*pi^2 0 0]; p1=[1 20*pi]; p2=[1 50*pi]; p3=[1 2e5*pi]; p4=[1 2e6*pi]; d=conv(conv(p1,p2),conv(p3,p4)); bode(n,d) 60 Gain dB 40 20 0 -20 -40 -60 10 -1 10 0 10 1 10 2 10 4 10 5 10 3 Frequency (rad/sec) 10 6 10 7 10 8 10 0 10 1 10 2 10 4 10 5 10 3 Frequency (rad/sec) 10 6 10 7 10 8 200 Phase deg 100 0 -100 -200 10 -1 10-18 10.55 Using MATLAB: n=[2e7*pi 0]; d=conv([1 20*pi],[1 2e4*pi]); w=2*pi*[5 500 50000]; a=freqs(n,d,w); am=abs(a); ap=angle(a)*180/pi Magnitudes: 447.2135 998.5526 196.1161 Phases: 63.4063 -1.7166 -78.6786 (a) vO = 0.447sin(10πt + 63.4 o ) V (b) vO = 0.999sin(1000πt −1.72 o ) V (c ) vO = 0.196sin(105 πt − 78.7 o ) V 10.56 Av (s) = 10 4 s s + 200π Av (jω ) = | Av ( jω )= 10 4 f 10 4 jω 10 4 jf = jω + 200π jf + 100 | ∠Av (jω )= 90 o − tan −1 f 2 + 1002 (a) 1 Hz : A (jω ) = 100 | ∠A (jω )= 89.4 | (b) 50 Hz : A (jω ) = 4472 | ∠A (jω )= 63.4 (c) 5 kHz : A (jω ) = 9998 | ∠A (jω )= 1.15 o v v o v v o v v f 100 ( ) vO = 0.03 sin 2πt + 89.4 o V ( ) = 3.00 sin (10 πt + 1.15 ) V | vO = 1.34 sin 100πt + 63.4 o V | vO 4 o 10.57 Using MATLAB: n=[1e4 0]; d=[1 200*pi]; w=2*pi*[2 2000 200000]; a=freqs(n,d,w); am=abs(a); ap=angle(a)*180/pi Magnitudes: 2.0000e+02 9.9875e+03 1.0000e+04 Phases: 88.8542 2.8624 0.0286 (a) vO = 2.00sin 4πt + 88.9o mV ( ) (b) v = 0.999sin(4000πt + 2.86 )V (c) v = 0.100sin(4x10 πt + 0.0286 )V o O 5 o O 10-19 10.58 Using MATLAB: n=[-1e7 0]; d=[1 1e5 1e14]; w=2*pi*[1.59e6 1e6 5e6]; a=freqs(n,d,w); am=abs(a) ap=angle(a)*180/pi Magnitudes: 98.1550 1.0381 0.3542 Phases: -168.9767 -90.5948 90.2029 (a) vO = 0.393sin 3.18x106 πt −169o V ( ) (b) v = 4.15sin(2x10 πt − 90.6 )mV (c) v = 1.42sin(10 πt + 90.2 )mV 6 o O 7 o O 10.59 Using MATLAB: n=[-20 0 -2e13]; d=[1 1e4 1e12]; w=2*pi*[1.59e5 5e4 2e5]; a=freqs(n,d,w); am=abs(a) ap=angle(a)*180/pi Magnitudes: 3.8242 19.9999 19.9953 Phases: 101.0233 179.8003 -178.7570 (a) vO = 0.956sin 3.18x105 πt + 101o mV ( ) (b) v = 5.00sin(10 πt + 180)V (c) v = 5.00sin(4x10 πt −179 )V 5 O 5 o O 10.60 Using MATLAB: n=[4e14*pi^2 0 0]; p1=[1 20*pi]; p2=[1 50*pi]; p3=[1 2e5*pi]; p4=[1 2e6*pi]; d=conv(conv(p1,p2),conv(p3,p4)); w=2*pi*[5 500 50000]; a=freqs(n,d,w); am=abs(a) ap=angle(a)*180/pi Magnitudes: 87.7058 998.5400 893.3111 Phases: 142.1219 3.6930 -29.3873 (a) vO = 175sin 10πt + 142o mV ( ) (b) v = 2.00sin(1000πt + 3.69 )V (c) v = 1.79sin(10 πt − 29.4 )V o O 5 O 10-20 o 10.61 26 (a) Amid = +10 20 = +20 | Av = 1+ (b) A v =− 20 s ( 2π x 5 x 106 = ) 20 2x108 π = s s +10 7 π 1+ 7 10 π 2x10 π s +10 7 π 8 10.62 (a) A mid = +10 (b) Av (s)= − 40 20 = +100 | Av (s) = 100 s ⎛ ⎞ s (s + 400π )⎜⎝1+ 2π x 105 ⎟⎠ = 2π x 10 7 s (s + 400π )(s + 2π x 10 ) 5 2π x 10 7 s (s + 400π )(s + 2π x 10 ) 5 10-21 10.63 ⎛ ⎞2 ⎜ ⎟ ⎛ 50000π ⎞ 1 Av (s) = −1000⎜ ⎟ = −1000⎜ ⎟ | A mid = −1000 s ⎝ s + 50000π ⎠ ⎜1+ ⎟ ⎝ 50000π ⎠ ⎛ dB dB ⎞ f H = 0.64 f1 = 0.644(25kHz) = 16.1 kHz | 2⎜ −20 ⎟ = −40 ⎝ dec dec ⎠ 2 Using MATLAB: n=1000*(50000*pi)^2; d=[1 2*50000*pi (50000*pi)^2 ]; bode(n,d) 60 Gain dB 50 40 30 - 40 dB/dec 20 10 0 10 4 10 5 Frequency (rad/sec) 10 6 0 Phase deg -50 -100 -150 -200 10 4 10-22 10 5 Frequency (rad/sec) 10 6 10.64 ⎞3 A ⎛ ⎛ ω1 ⎞ 3 ω 1 ⎟ = o Av (s) = Ao ⎜ ⎟ | Av ( jω H ) = Ao ⎜⎜ ⎟ 2 2 2 ⎝ s + ω1 ⎠ ⎝ ω H + ω1 ⎠ | BW = f H 1 ⎛ f H ⎞2 ⎛ dB ⎞ dB 2 = 1+ ⎜ ⎟ → f H = f1 2 3 −1 = 25kHz(0.5098) = 12.8 kHz | 3⎜ -20 ⎟ = −60 ⎝ dec ⎠ dec ⎝ f1 ⎠ 1 3 Using MATLAB: n=2000*(50000*pi)^3; d=[1 3*50000*pi 3*(50000*pi)^2 (50000*pi)^3]; bode(n,d) Bode Diagrams 70 60 50 40 30 -60 dB/dec 20 10 200 150 100 50 0 -50 -100 10 4 10 5 10 6 Frequency (rad/sec) 10-23 10.65 (a) To avoid distortion of the waveform, the phase shift must be proportional to frequency. 30o at 1500 Hz and 50o at 2500 Hz. o o o (b) vO = 3.16sin 1000πt + 10 + 1.05sin 3000πt + 30 + 0.632sin 5000πt + 50 ( ) ( ) ( ) (c) Using MATLAB: t=linspace(0,.004); a=10^(10/20); vs=sin(1000*pi*t)+0.333*sin(3000*pi*t)+0.200*sin(5000*pi*t); vo=A*(sin(1000*pi*t+pi/18)+0.333*sin(3000*pi*t+3*pi/18)+0.2*sin(5000*pi*t+5*pi/18)); plot(t,A*vs,t,vo) 3 2 1 0 -1 -2 -3 0 0.5 1 1.5 2 2.5 3 3.5 4 x 10 10-24 -3 CHAPTER 11 11.1 v O = vS iS = v 1MΩ 1kΩ 1000) | Av = O = 990 or 59.9 dB ( vS 1MΩ + 5kΩ 1kΩ + 0.5Ω vS 990vS and iO = 1MΩ + 5kΩ 1kΩ ( | Ai = iO 990 6 = 10 = 9.9x105 or 120 dB iS 1000 ) AP = Av Ai = 990 9.9x105 = 9.8x108 or 89.9 dB | v S = vO 5V = = 5.05 mV AV 990 11.2 vO = vS vs = 5kΩ 1kΩ v 31.6) and A v = O = 7.91 or 18.0 dB ( vS 5kΩ + 5kΩ 1kΩ + 1kΩ vO 10V = = 1.27 V Since Rout has the same value as R L , the power Av 7.91 dissipated in Rout is also 0.5W. The power dissipated in R id will be ⎛ VS ⎞2 ⎜ ⎟ V2 ⎝ 2 ⎠ V2 V = S where VS = O and VO = 2(0.5W )(1000Ω) = 31.6V PI = id = 2Rid 2Rid 8Rid 7.91 42 PI = = 0.4mW. The total power dissipated in the amplifier is 8(5000) P = 500mW + 0.4mW = 500 mW. 11.3 0.99mV ≥ 1mV 11.4 Io = 2(100W ) 50Ω Rid ⇒ R id ≥ 4.95 MΩ Rid + 50kΩ = 2 A and I2o Rout ≤ 5W or Rout ≤ 2.5Ω 2 11.5 v id = 11.6 vid = vO 10V 10V = 5 = 0.1 mV | ≤ 10−6V requires A ≥ 10 7 or 140 dB A A 10 vO 15V 15V 15µV = 6 = 15 µV | ≤ 10−6 V requires A ≥ 15x106 or 144 dB | i+ = = 15 pA A 1MΩ A 10 11-1 11.7 (a) A =− R2 220kΩ =− = −46.8 | 20log(46.8) = 33.4 dB | Rin = R1 = 4.7 kΩ | Rout = 0 Ω R1 4.7kΩ (b) A v =− R2 2.2 MΩ =− = −46.8 | 20log(46.8)= 33.4 dB | Rin = R1 = 47 kΩ | Rout = 0 Ω R1 47kΩ (a) A =− R2 120kΩ =− = −10.0 | 20log(10.0)= 20.0 dB | Rin = R1 = 12 kΩ | Rout = 0 Ω R1 12kΩ (b) A =− R2 330kΩ =− = −2.36 | 20log(2.36)= 7.46 dB | Rin = R1 = 140 kΩ | Rout = 0 Ω R1 140kΩ (c) A =− R2 240kΩ =− = −55.8 | 20log(55.8)= 34.9 dB | Rin = R1 = 4.3 kΩ | Rout = 0 Ω R1 4.3kΩ v 11.8 v v v 11.9 Av = − Is = R2 8200Ω =− = −10.9 | VO = −10.9(0.05V )= −0.547V 750Ω R1 | vo (t )= −0.547sin (4638t ) V Vs 0.05V = = 66.7µA | is (t )= 66.7sin (4638t ) µA R1 750Ω 11.10 110kΩ (a) A = − 22kΩ = −5 v = A v = 0 (b) V = A V = -5(0.22V )= −1.10 V (b) v = [−5(0.15V )]sin 2500πt = −0.75sin 2500πt V (d ) v = (−1.10 + 0.75sin 2500πt ) V v o v s O v S o (e) I S (f ) i (g ) v O - 11.11 o = ⎡0.15V ⎤ 0.22V = 10.0 µA is = ⎢ ⎥ sin 2500πt = 6.82sin 2500πt µA iS = (10.0 - 6.82sin 2500πt ) µA 22kΩ ⎣ 22kΩ ⎦ = -iS IO = −10.0 µA io = −6.82sin 2500πt µA iO = (-10.0 + 6.82sin 2500πt ) µA =0 vO = −iTH R 11.12 40 R Rin = R1 = 1.5 kΩ | Av = − 2 = −10 20 = −100 → R2 = 100R1 = 150kΩ R1 The resistors exist as standard values. 11-2 11.13 26 Rin = R1 = 30 kΩ | Av = − R2 = −10 20 = −20 → R2 = 20R1 = 600kΩ R1 Using the closest values from Appendix A, R1 → 30.1 kΩ and R2 → 604 kΩ The values for the final design are Av = − 604 kΩ = −20.1 and Rin = 30.1 kΩ 30.1 kΩ 11.14 12 R Rin = R1 = 100 kΩ | Av = − 2 = −10 20 = −15.8 → R2 = 15.8R1 = 1.58 MΩ R1 Using the closest 1% values from Appendix A, R1 →100 kΩ and R2 →1.00 MΩ + 576kΩ 1.576MΩ = −15.8 and Rin = 100 kΩ 100 kΩ If we used 5% values, we could select 100 kΩ and 1.6 MΩ. The values for the final design are Av = − 11.15 Av = 1+ R2 750kΩ = 1+ = 92.5 | 20 log(92.5) = 39.3 dB | Rin = ∞ | Rout = 0 Ω R1 8.2kΩ 11.16 (a) A = 1+ R2 120kΩ = 1+ = 6.00 | 20 log(6.00)= 15.6 dB | Rin = ∞ | Rout = 0 Ω R1 24kΩ (b) A = 1+ R2 300kΩ = 1+ = 21.0 | 20 log(21.0)= 26.4 dB | Rin = ∞ | Rout = 0 Ω 15kΩ R1 (c) A = 1+ R2 360kΩ = 1+ = 84.7 | 20 log(84.7) = 38.6 dB | Rin = ∞ | Rout = 0 Ω 4.3kΩ R1 v v v 11.17 Av = 1+ R2 8200Ω = 1+ = 10.0 | VO = 10.0(0.05V )= 0.500V | vo (t )= 0.500sin 9125t V 910Ω R1 11-3 11.18 110kΩ (a) A = 1+ 22kΩ = +6 v = 6v = 0 (b) V = A V (b) v = [6(0.18V )]sin 3250πt = 1.08sin 3250πt V (d ) v = (1.98 −1.08sin 3250πt ) V (e) i = 0 v o s O v S = 6(0.33V )= +1.98 V o o (f ) i O S =+ vO R1 + R2 IO = 1.98V = 15.0 µA io = 8.18sin 3250πt µA iO = (15.0 + 8.18sin 3250πt ) µA 132kΩ (g ) v = (0.33 − 0.18sin 3250πt ) V - 11.19 (a) A nom v = 1+ R2 47kΩ = 1+ = 262 R1 0.18kΩ | 20 log(262) = 48.4 dB Rin = 10kΩ + ∞ = ∞ | Rout = 0 Ω (b) A max v = 1+ 47kΩ(1.1) 0.18kΩ(0.9) = 320 | Avmin = 1+ Avmax − Avnom 320 − 262 = = 0.22 | 262 Avnom (c) Tolerances : + 22%, −18% 47kΩ(0.9) 0.18kΩ(1.1) = 215 Avmin − Avnom 215 − 262 = = −0.18 262 Avnom (d ) 320 = 1.49 :1 215 (e) function count=c; c=0; for i=1:500, r1=180*(1+0.2*(rand-0.5)); r2=47000*(1+0.2*(rand-0.5)); a=1+r2/r1; anom=1+47000/180; if (a>=0.95*anom & a<=1.05*anom), c=c+1; end; end c Executing this function twenty times yields 44% . 11.20 32 R Av = 1+ − 2 = 10 20 = 39.8 → R2 = 38.8R1 R1 There are many possible pairs of values in Appendix A. Two choices are R1 → 3.09 kΩ and R2 → 121 kΩ or R1 → 6.19 kΩ and R2 → 243 kΩ The values for the final design are Av = 1+ 11.21 11-4 121 kΩ = 40.2 3.09 kΩ 26 R Av = 1+ − 2 = 10 20 = 20 → R2 = 19R1 R1 There are many possible pairs of values in Appendix A. Two choices are R1 → 1.05 kΩ and R2 → 200 kΩ or R1 → 10.5 kΩ and R2 → 200 kΩ The values for the final design are Av = 1+ 200 kΩ = 20.0 1.05 kΩ 11.22 6 R Av = 1+ − 2 = 10 20 = 2.00 → R2 = R1. Any value could theoretically be used, but R1 we don' t want a heavy load on a real op amp, so we should choose the resistors to be at least in the 10 - kΩ range or so. A third 100 - kΩ resistor is added in shunt with the input as in Fig. P11.23(b). R1 → 10.0 kΩ, R2 →10.0 kΩ, and R3 →100 kΩ The values for the final design are Av = 1+ 10.0 kΩ = 2.00 and Rin = 100 kΩ 10.0 kΩ 11.23 R2 100kΩ =− = −5.00 | Rin = R1 = 20 kΩ R1 20kΩ (a) A =− (b) A = 1+ (c) A =− v v v R2 100kΩ = 1+ = +6.00 | Rin = 47kΩ ∞ = 47 kΩ 20kΩ R1 R2 0 =− = 0 | Rin = R1 = 36 kΩ R1 36kΩ (This is not a very useful circuit except possibly as an "electronic ground".) 11.24 vO = − R3 R 51kΩ 51kΩ v1 − 3 v2 = − v1 − v2 = −51v1 − 25.5v2 1kΩ R1 R2 2kΩ [ ] [ ] vO (t )= −51(0.01) sin 3770t + −25.5(0.04) sin10000t vO (t )= (−0.510sin 3770t −1.02sin10000t ) V and v- (t )≡ 0 11-5 11.25 ⎡ R ⎤ ⎡ R ⎤ ⎡ R ⎤ ⎡ ⎤ v ⎥ + () v ⎥ + (0)⎢− v ⎥ = −0.3750sin 4000πt V 1 ⎢− 1 ⎢− (a) v = (0)⎢⎣− 2R v ⎥⎦ + () ⎣ 4R ⎦ ⎣ 8R ⎦ ⎣ 16R ⎦ O S ⎡ R S ⎤ ⎡ R R S ⎤ ⎡ R s ⎤ ⎡ ⎤ 1 ⎢− v ⎥ + (0)⎢− v ⎥ + () v ⎥ + () v ⎥ = −0.6875sin 4000πt V 1 ⎢− 1 ⎢− (b) v = () ⎣ 2R ⎦ ⎣ 4R ⎦ ⎣ 8R ⎦ ⎣ 16R ⎦ O S (c) v S R S S = − Asin 4000πt V where the amplitude A is in the table below: O 0000 0 0100 -0.250 V 1000 -0.5000 V 1100 -0.7500 V 0001 -0.0625 V 0101 -0.3125 V 1001 -0.5625 V 1101 -0.8125 V 0010 -0.1250 V 0110 -0.3750 V 1010 -0.6250 V 1110 -0.8750 V 0011 -0.1875V 0111 -0.4375 V 1011 -0.6875 V 1111 -0.9375 V 11.26 Ron = 1 | The worst - case condition for the switches occurs ⎛W ⎞ K ⎜ ⎟(VGS − VTN − VDS ) ⎝ L⎠ ' n for the one with VDS ≠ 0 and VSB = 0. If VREF = 3V and Ron = 0.01(10kΩ)= 100Ω VD = 3V and VS = 3V ( 10kΩ = 2.97V | VDS = 0.03V 10kΩ + 100Ω ) VTN = 1 + 0.5 2.97 + 0.6 − .6 = 1.56V ⎛W ⎞ ⎛ 455 ⎞ 1 =⎜ ⎜ ⎟= ⎟ −5 ⎝ L ⎠ 5x10 (100) (5 − 2.97)−1.56 − 0.03 ⎝ 1 ⎠ [ ] ⎛W ⎞ ⎛ 50 ⎞ 1 When the grounded transistor is on, VDS = 0 | ⎜ ⎟ = =⎜ ⎟ −5 ⎝ L ⎠ 5x10 (100)[5 −1− 0] ⎝ 1 ⎠ 11.27 (a ) Using Eq. 11.32, A v (b) R in2 (c) v O 11-6 = v2 i2 =− R2 10R =− = −10 R R1 = 11R = 110 kΩ v1 = 0 | Rin1 = v1 i1 v = −10(v1 − v2 )= −30 + 15cos8300πt V = R = 10 kΩ 2 =0 (d ) v O = −30 + 30cos8300πt V 11.28 V1 = 3.2 V | V2 = 3.1 V | VO = − (3.20 − 2.82)V = 3.80 µA R2 10R V1 − V2 )= − ( (3.2 − 3.1)= −1.00 V R R1 10R = 2.82 V | V- =V += 2.82 V R + 10R 100kΩ V −V 3.2 − 2.82 V V − V 3.1− 2.82 V I1 = 1 − = = 3.80 µA | I2 = 2 + = = 2.80 µA 100 100 kΩ 100kΩ 100kΩ kΩ V2 3.1V Checking : I2 = = = 2.82 µA which agrees within roundoff error. R + 10R 110kΩ IO = | V+ = 3.1V 11.29 ⎛ R ⎞⎛ R ⎞ ⎛ 10kΩ ⎞⎛ 100kΩ ⎞ Av = −⎜ 4 ⎟⎜1+ 2 ⎟ = −⎜ ⎟⎜1+ ⎟ = −51 2kΩ ⎠ ⎝ R3 ⎠⎝ R1 ⎠ ⎝ 10kΩ ⎠⎝ [ ] vO = Av (v1 − v2 ) = −51(0.1) sin 2000πt + (−51)(2 − 2.1)= (5.1− 5.1sin 2000π ) V 11.30 ⎛ R ⎞⎛ R ⎞ ⎛ 20kΩ ⎞⎛ 100kΩ ⎞ Av = −⎜ 4 ⎟⎜1+ 2 ⎟ = −⎜ ⎟⎜1+ ⎟ = −12 20kΩ ⎠ ⎝ R3 ⎠⎝ R1 ⎠ ⎝ 10kΩ ⎠⎝ vO = Av (v1 − v 2 ) = −12(4 − 0.1sin 4000πt − 3.5) = (−6 + 1.2sin 4000π ) V 11.31 1 vO (t ) = − RC t 1 ∫ v S (τ ) dτ + vC (0 )= − 10kΩ(0.005µF ) ∫ 0.1sin2000πτ dτ + 0 = 0.318cos2000πt V 0 0 t + 11.32 vO vS 1 ms 2 ms t 5V t -5 V 0 11.33 (a) A v 1 ms 2 ms ⎛R ⎞ 1 = −⎜ 2 ⎟ ⎝ R1 ⎠ 1+ s ωH (b) A (0) = − R R2 v 1 =− | Av (0) = − R2 10kΩ 1 1 =− = −5 | f H = = = 15.9 kHz R1 2kΩ 2πR2C 2π (10kΩ)(0.001µF ) 56kΩ 1 1 = −20.7 | f H = = = 28.4 kHz 2.7kΩ 2πR2C 2π (56kΩ)(100 pF ) 11-7 11.34 20 (a) Rin = R1 → R1 = 10 kΩ | Av (0)= −10 20 = −10 → R2 = 10R1 = 100 kΩ C= 1 1 = = 79.6 pF 2πR2 f H 2π (100kΩ)(20kHz) (b) If the input resistance specification is most critical, R1 = 10 kΩ | R2 = 10R1 = 100 kΩ | C = 82 pF → f H = 19.4 kHz If the cutoff frequency specification is most critical, C = 82 pF → f H = 19.9 kHz | R1 = 9.76 kΩ | R2 = 10R1 = 97.6 kΩ 11.35 sCVs = − Vo R | T(s) = 11.36 vO (t )= −RC 11.37 Av (s)= − dvS (t ) dt Z2 (s) Z1 (s) Vo = −sRC Vs = −(100kΩ)(0.02µF ) Z2 = R2 Z1 (s)= d 2cos3000πt = +37.7sin 3000πt V dt R1 sCR1 + 1 Av (s)= − R2 ⎛ s ⎞ 1 ⎜1+ ⎟ for ω L = R1C R1 ⎝ ω L ⎠ 11.38 (a) A v =− R2 120kΩ =− = −6.00 | Rin = R1 = 20 kΩ R1 20kΩ Note that the 100 - kΩ resistor does not affect the circuit because v- = 0. (b) A = 1+ (c) A =− v v R2 120kΩ = 1+ = +9.00 | Rin = 75kΩ ∞ = 75 kΩ 15kΩ R1 R2 0 =− = 0 | Rin = R1 = 160 kΩ R1 36kΩ (This is not a very useful circuit except possibly as an "electronic ground".) 11-8 11.39 Equating currents at the inverting input node (virtual ground): 20kΩ vS vO =− 10kΩ 100kΩ + 20kΩ 100kΩ 100kΩ + 20kΩ ( ) 116.7kΩ(120kΩ) vO =− = −70.0 vS 10kΩ(20kΩ) Av = Rin = 10 kΩ Rout = 0 11.40 The inverting terminal of the op amp represents a virtual ground (0 V). V − (−V ) 0 − (−10) (a) I = I = R = 10 = 1 A (b) Saturation requires V ≥ V − V where V = V 2() 1 2I V −V = = =2.83V → V ≥ 2.83 V − O EE D DS GS TN DS DD − V− = VDD and D GS TN (c) P R DD 0.25 Kn = I 2 R = () 1 10 = 10W. So the resistor must dissipate 10 W. 2 A 15 - W resistor would provide a reasonable safety margin. 11.41 The inverting terminal of the op amp represents a virtual ground (0 V). ⎛ β ⎞⎡V− − (−VEE )⎤ ⎛ 30 ⎞⎡ 0 − (−15)⎤ ⎥ = ⎜ ⎟⎢ ⎥ = 0.484 A (a) IO = IC = α F I E = ⎜ F ⎟⎢ R 30 31 ⎝ ⎠ ⎝ 1+ β F ⎠⎢⎣ ⎥⎦ ⎢⎣ ⎥⎦ (b) VO = V− + VBE = 0 + VBE = VBE = VT ln IC 0.484 = 0.025V ln −13 = 0.730V IS 10 (c) Forward - active region operation requires VCE ≥ VBE but VCE = VCC − V− = VCC Therefore VCC ≥ 0.730 V. (d ) PR = I 2 R = (0.484) 30 = 7.03W. So the resistor must dissipate 7.03 W. 2 A 10W resistor would provide a reasonable safety margin. PD = ICVCE + I BVBE = 0.484(15)+ 0.484 0.730 = 7.27 W. 30 11-9 11.42 Z2 (s) (a) A (s)= − Z v 1 (b) (s) Z2 = 1 sC Z1 (s) = R Av (s )= − 1 , an inverting integrator. sRC VS − V+ VO − V+ V R1 + = sCV+ and V+ = V− = VO = O R KR R1 + KR1 1+ K Combining these expressions yields : A V (s)= Vo 1+ K =+ , a noninverting integrator. sRC Vs 11.43 R1 V V − V+ Vo − V+ = o | s + = sCV+ | V+ = V− R1 + 9R1 10 R 10R ⎛ 11 ⎞ V V 100 Vs = ⎜ sCR + ⎟ o | o = - - The circuit becomes a low - pass filter. ⎝ Vs 10sCR + 11 10 ⎠ 10 -------Note : The pole moves to the right half plane if the tolerances go the other way. V 99 For example, if KR1 = 10R1 and KR = 9R, o = Vs 9sCR −1 V− = Vo 11.44 (a) Applying ideal op-amp assumption 1, the voltage at the top end of R is v1 and the voltage at the bottom end of R is v2. Applying op-amp assumption 2, the current iO must also equal the current in R, so v − v2 iO = 1 R + v O1 vx v1 i + x R (b) i X = 0V − 0V v = 0 | Rout = X = ∞ R iX v O1 = A(0 − (v O1 + v X )) v2 A v | v1 = v O1 + v X = X 1+ A 1+ A v − v2 vX v iX = 1 = | R out = X = (1+ A)R R iX (1+ A)R v O1 = − v X v O2 + 11-10 v O2 = A(0 − v O2 ) ⇒ v O2 = 0 11.45 v +v 2 v = - O 2 i v R 1 R 1 3 i v 5 + R v R 2 4 R 2 v +v 2 v+ = O 2 v O v + i Z O O L (a) iO = v5 − vO R | v 5 = v− − i R3 = v− − v− = v2 + vO 2 and v 5 = v 2 − v1 + v O | i O = v X i 2 R R 1 v1 − v− R3 = 2v− − v1 since R1 = R3 R1 v 2 − v1 + v O − v O v 2 − v1 = R R 3 v 5 i v + R R 2 X 4 R v X 2 v X + i R = R = R = R 1 2 3 4 v X (b) iX = vX − v5 vX − vX v = = 0 | Rout = X = ∞ R R iX X + - (an ideal current source) 11-11 11.46 (a) Using voltage division since i + = 0, v 2 = v 4 + 6 4.99kΩ 4.99kΩ + 5.00kΩ 4.99kΩ v 2 = v 4 + (6 − v 4 ) = 0.5005v 4 + 2.997V 4.99kΩ + 5.00kΩ 4 − v1 Since v id = 0, v 1 = v 2 and v 5 = v 1 − (5.01kΩ) 5kΩ Solving for v 5 yields v 5 = 1.992V + 1.002v 4 io = v5 − v4 = 199µA + 2x10−7 v 4 10kΩ v 4 is unknown; let us assume 2x10-7 v 4 << 199x10−6 A which requires v 4 << 995V . So for v 4 < 100V,which should almost always be true in transistor circuits, i O = 199µA. For ZL = 10 kΩ, v4 = 1.99 V, v2 = 3.99 V, v1 = 3.99 V, v5 = 3.99 V Note that v5 - v4 = 2 V = (6V - 4V) 5.01 k Ω v1 i R v 4V 1 i R 1 3 v 5k Ω 5 + R R 2 6V v 2 5k Ω v2 4 v4 10 k Ω 4.99 k Ω v4 + i Z 11-12 L O 11.46 (b) v R i 5.01 k Ω 1 i R 1 3 v 5k Ω 5 + R R 2 5k Ω v 10 k Ω 4 R 4.99 k Ω 2 v X + i v X Rout = vX v − v5 and i X = X iX 10kΩ X + - So we need to find iX, and hence v5, in terms of vX 5.00kΩ = 0.5005v X 4.99kΩ + 5.00kΩ v v 5 = v 1 + i (5.01kΩ)= v 1 + 1 (5.01kΩ) = 2.002 v 1 = 1.002 v x 5kΩ 0.002 v X v − v 5 v X −1.002 v X iX = X = =− and Rout = −5 MΩ ! A negative output resistance! 10kΩ 10kΩ 10kΩ v1 = v2 = vX 11.47 IL = IS + VO − I L RL R1 VO = I L RL + I S R2 ⎡ ⎛ R ⎞⎤ VS = I S R2 + I L RL = I S ⎢ R2 + RL ⎜1+ 2 ⎟⎥ ⎝ R1 ⎠⎦ ⎣ ⎛ R⎞ I L = I S ⎜1+ 2 ⎟ ⎝ R1 ⎠ ⎛ R⎞ Rin = R2 + RL ⎜1+ 2 ⎟ ⎝ R1 ⎠ Apply test voltage vx to the output with I S = 0. Then v+ = vx , vO = vx , and ix = i− + vx − vx = 0 + 0 = 0. Rout = ∞ R1 For finite gain : Rout = v X − vO = vX iX where i X = v X − vO R1 and vO = v X A 1+ A vX and Rout = R1 (1+ A) 1+ A 11.48 11-13 Using the result from Prob. 11.47, ⎛ R⎞ ⎛ 1kΩ ⎞ Rin = R2 + RL ⎜1+ 2 ⎟ = 1kΩ + 3.6kΩ⎜1+ ⎟ = 4.96 kΩ ⎝ 10kΩ ⎠ ⎝ R1 ⎠ Rout = ∞ 11.49 Applying op-amp assumption 1 to the circuit below, the voltage at the top of R2 is vO2, and applying op-amp assumption 2, vS v = − O2 R1 R2 or v O2 = − v S R2 R1 Since the op-amp input currents are zero, and i= vS , R1 ⎛R R ⎞ v O1 = −iR2 − iR3 = −⎜ 2 + 3 ⎟ v S ⎝ R1 R1 ⎠ Alternatively, the voltage at the bottom of R2 is zero, so ⎛ R ⎞ ⎛ R ⎞⎛ R ⎞ ⎛R R ⎞ v O1 = ⎜1+ 3 ⎟ v O2 = ⎜1+ 3 ⎟⎜− 2 ⎟v S = −⎜ 2 + 3 ⎟v S ⎝ R2 ⎠ ⎝ R2 ⎠⎝ R1 ⎠ ⎝ R1 R1 ⎠ + + i v O1 - R 3 i R R v 1 2 i + + S v - 11.50 Rin = vS iS 11-14 iS = vS − vO 15kΩ ⎛ 30kΩ ⎞ vO = ⎜1+ ⎟v S = 16vS 2kΩ ⎠ ⎝ iS = O2 vS −16vS −15vS = 15kΩ 15kΩ Rin = -1kΩ 11.51 An n-bit DAC requires (n+1) resistors. Ten bits requires 11 resistors. 210 R 210 = or 1024 :1 R 1 A wide range of resistor values is required but it could be done. For R = 1 kΩ, 1024R = 1.024 MΩ. 11.52 ⎛ R ⎛ 1 1⎞ R⎞ + VO = −VREF ⎜ ⎟ = −3.0⎜ + ⎟ = −1.1250 V ⎝ 4R 8R ⎠ ⎝ 4 8⎠ ⎛ R ⎛1 1 ⎞ R ⎞ + VO = −VREF ⎜ ⎟ = −3.0⎜ + ⎟ = −1.6875 V ⎝ 2R 16R ⎠ ⎝ 2 16 ⎠ 0000 0.0000 V 1000 -1.5000 V 0001 -0.1875 V 1001 -1.6875 V 0010 -0.3750 V 1010 -1.875 V 0011 -0.5625 V 1011 -2.0625 V 0100 -0.7500 V 1100 -2.2500 V 0101 0.9375 V 1101 -2.4375 V 0110 -1.1250 V 1110 -2.6250 V 0111 -1.3125 V 1111 -2.8125 V 11.53 Taking successive Thévenin equivalent circuits at each ladder node yields: 0001 0010 0100 1000 VTH RTH vO VREF/16 VREF/8 VREF/4 VREF/2 R R R R -0.3125 V -0.6250V -1.250 V -2.500 V 11.54 The ADC code is equivalent to 2-1 + 2−3 + 2−5 + 2−7 + 2−9 + 2−10 + 2−13 x VFS = 0.66711426 x VFS ( ) The ADC input may be anywhere in the range : ⎛ ⎞ 1 ⎜0.66711426 ± LSB⎟ x VFS = 3.4154625V ± 0.15625mV | 3.415469V ≤ VX ≤ 3.415781V 2 ⎝ ⎠ 11.55 11-15 (a) 1 LSB = 2 2V = 1.90735 µV bits 20 1.63V 20 2 = 854589.4 bits → 85458910 = 110100001010001111012 2V 0.997003V (c) 2V 220 = 522716.7 bits → 52271710 = 011111111001110111012 (b) 11.56 The time corresponding to 1 LSB is TLSB = 0.2s = 190.7 ns | 0.1TLSB = 19.1 ns 2 20 bits 11.57 VO (ω ) = 1 RC TT ∫ v (t )dt = 0 For θ = 0, VO (ω ) = 1 RC TT ∫ VM cos(ωt + θ )dt = 0 VM sin ωTT VM TT = RC ω RC VM ωt +θ V cos x dx = M [sin(ωTT + θ ) − sin θ ] ∫ ωRC θ ωRC ⎛ sin ωTT ⎞ ⎟ ⎜ ⎝ ωTT ⎠ 11.58 Combine amplifiers A & B; Combine amplifiers B & C 11.59 R + v 1 =0 OUT -10 v - v 1 - + v 2 O - 10 k Ω + + v =0 OUT -5 v 2 - 24 k Ω R + +50 v 1 24 k Ω v 1 O - Av = 50, Rin = 24 kΩ, Rout = 0 11.60 ⎛ 240kΩ ⎞⎛ 50kΩ ⎞ Av = ⎜− ⎟⎜− ⎟ = +50 | Rin = RinA = 24 kΩ | Rout = RoutB = 0 ⎝ 24kΩ ⎠⎝ 10kΩ ⎠ 11.61 ⎛ 390kΩ ⎞⎛ 100kΩ ⎞ Av = ⎜1+ ⎟⎜1+ ⎟ = +48.0 | Rin = RinA = ∞ | Rout = RoutB = 0 ⎝ 47kΩ ⎠⎝ 24kΩ ⎠ 11.62 11-16 ⎛ 120kΩ ⎞⎛ 120kΩ ⎞ = ⎜1+ ⎟⎜− ⎟ = −42.0 | Rin = RinA = ∞ | Rout = RoutB = 0 20kΩ ⎠⎝ 20kΩ ⎠ ⎝ ⎛ 120kΩ ⎞⎛ 120kΩ ⎞ (b) Av = ⎜⎝− 20kΩ ⎟⎠⎜⎝1+ 20kΩ ⎟⎠ = −42.0 | Rin = RinA = 20 kΩ | Rout = RoutB = 0 (a) A v 11.63 + + v -20 v 1 - v 1 -20 v 2 - 2k Ω + + - -8000 v v -20 v 3 2k Ω + 2 kΩ v 3 O - + 1 v O 1 - v 2 2k Ω - ⎛ 40kΩ ⎞⎛ 40kΩ ⎞⎛ 40kΩ ⎞ 3 Av = ⎜− ⎟⎜ − ⎟⎜− ⎟ = (−20) = −8000 | Rin = RinA = 2 kΩ | Rout = RoutC = 0 ⎝ 2kΩ ⎠⎝ 2kΩ ⎠⎝ 2kΩ ⎠ 11.64 ⎛ 40kΩ ⎞⎛ 40kΩ ⎞⎛ 40kΩ ⎞ ⎛ 40kΩ ⎞3 Av = ⎜− ⎟⎜ − ⎟⎜− ⎟ = ⎜− ⎟ = −1080 | Rin = RinA = 3.9 kΩ | Rout = RoutC = 0 ⎝ 3.9kΩ ⎠⎝ 3.9kΩ ⎠⎝ 3.9kΩ ⎠ ⎝ 3.9kΩ ⎠ 11.65 40 ⎛ 40kΩ ⎞⎛ 40kΩ ⎞⎛ 40kΩ ⎞ ⎛ 40kΩ ⎞3 20 | A = −10 = -100 − − = − Av = ⎜− ⎟⎜ ⎟⎜ ⎟ ⎜ ⎟ v R ⎠⎝ R ⎠⎝ R ⎠ ⎝ R ⎠ ⎝ 40kΩ = 8.62 kΩ | Rin = RinA = 8.62 kΩ | Rout = RoutC = 0 R= 3 100 11.66 (a) A v ⎛ 470kΩ ⎞⎛ 150kΩ ⎞⎛ 270kΩ ⎞ = ⎜− ⎟⎜− ⎟⎜ − ⎟ = −1500 | Rin = RinA = 47 kΩ | Rout = RoutC = 0 ⎝ 47kΩ ⎠⎝ 15kΩ ⎠⎝ 18kΩ ⎠ (b) Moving from left to right, 0.010 V, 0 V, -10(.01) = -0.100 V, 0 V, -10(-0.100) = +1.00 V, 0 V, -15(1.00) = -15.0 V, The eighth node is the ground node at 0 V. 11-17 11.67 ⎛ 470kΩ ⎞⎛ 150kΩ ⎞⎛ 270kΩ ⎞ Avnom = ⎜− ⎟⎜ − ⎟⎜− ⎟ = −1500 ⎝ 47kΩ ⎠⎝ 15kΩ ⎠⎝ 18kΩ ⎠ ⎡ 470kΩ ⎛ 1.05 ⎞⎤ ⎡ 150kΩ ⎛ 1.05 ⎞⎤ ⎡ 270kΩ ⎛ 1.05 ⎞⎤ Avmax = ⎢− ⎟⎥ ⎢− ⎟⎥ ⎢− ⎟⎥ = −2025 ⎜ ⎜ ⎜ ⎣ 47kΩ ⎝ 0.95 ⎠⎦ ⎣ 15kΩ ⎝ 0.95⎠⎦ ⎣ 18kΩ ⎝ 0.95 ⎠⎦ ⎡ 470kΩ ⎛ 0.95⎞⎤ ⎡ 150kΩ ⎛ 0.95⎞⎤ ⎡ 270kΩ ⎛ 0.95⎞⎤ Avmin = ⎢− ⎟⎥ ⎢− ⎟⎥ ⎢− ⎟⎥ = −1011 ⎜ ⎜ ⎜ ⎣ 47kΩ ⎝ 1.05 ⎠⎦ ⎣ 15kΩ ⎝ 1.05 ⎠⎦ ⎣ 18kΩ ⎝ 1.05 ⎠⎦ Rinnom = RinA = 47 kΩ Rinmax = 47kΩ(1.05)= 49.4 kΩ Rinmin = 47kΩ(0.95)= 44.7 kΩ nom max min Rout = Rout = Rout = RoutC = 0 11.68 ⎛ 39kΩ ⎞⎛ 39kΩ ⎞⎛ 39kΩ ⎞ Av = ⎜1+ ⎟⎜1+ ⎟⎜1+ ⎟ = +2744 | Rin = 1MΩ ∞ = 1 MΩ | Rout = RoutC = 0 3kΩ ⎠⎝ 3kΩ ⎠ 3kΩ ⎠⎝ ⎝ 2.00 mV , 2.00 mV , 28.0 mV , 28.0 mV , 392 mV , 392 mV , 5.49 V , 0 V (Ground node) 11.69 ⎛ 39kΩ ⎞⎛ 39kΩ ⎞⎛ 39kΩ ⎞ Av = ⎜1+ ⎟⎜1+ ⎟⎜1+ ⎟ = +64000 | Rin = 2 MΩ ∞ = 2 MΩ | Rout = RoutC = 0 1kΩ ⎠⎝ 1kΩ ⎠ 1kΩ ⎠⎝ ⎝ 2.00 mV , 2.00 mV , 80.0 mV , 80.0 mV , 3.20V , 3.20 V , 128 V (not realistic), 0 V 11.70 3 nom v ⎛ 39kΩ ⎞ = ⎜1+ ⎟ = +2744 3kΩ ⎠ ⎝ max v ⎡⎛ 39kΩ ⎞⎛ 1.02 ⎞⎤ = ⎢⎜1+ ⎟⎜ ⎟⎥ = +3094 3kΩ ⎠⎝ 0.98 ⎠⎦ ⎣⎝ A 3 A Rinnom = 1MΩ ∞ = 1 MΩ 3 max v A ⎡⎛ 39kΩ ⎞⎛ 0.98 ⎞⎤ = ⎢⎜1+ ⎟⎜ ⎟⎥ = +2434 3kΩ ⎠⎝ 1.02 ⎠⎦ ⎣⎝ Rinmax = 1MΩ(1.02) = 1.02 MΩ Rinmin = 1MΩ(0.98)= 980 kΩ nom max min Rout = Rout = Rout = RoutC = 0 11.71 ⎛ 150kΩ ⎞⎛ 420kΩ ⎞⎛ 100kΩ ⎞ Av = ⎜1+ ⎟⎜ − ⎟⎜1+ ⎟ = −1320 | Rin = 75kΩ ∞ = 75 kΩ | Rout = RoutC = 0 20kΩ ⎠ 15kΩ ⎠⎝ 21kΩ ⎠⎝ ⎝ 5.00 mV , 5.00 mV , 55.0 mV , 0 V, -1.10 V , -1.10V , - 6.60 V , 0 V (Ground node) 11-18 11.72 ⎛ 150kΩ ⎞⎛ 420kΩ ⎞⎛ 100kΩ ⎞ Avnom = ⎜1+ ⎟⎜ − ⎟⎜1+ ⎟ = −1320 20kΩ ⎠ 15kΩ ⎠⎝ 21kΩ ⎠⎝ ⎝ ⎡⎛ 150kΩ ⎞⎛ 1.01 ⎞⎤ ⎡⎛ 420kΩ ⎞⎛ 1.01 ⎞⎤ ⎡⎛ 100kΩ ⎞⎛ 1.01 ⎞⎤ Avmax = ⎢⎜1+ ⎟⎜ ⎟⎥ ⎢⎜− ⎟⎜ ⎟⎥ ⎢⎜1+ ⎟⎜ ⎟⎥ = −1402 20kΩ ⎠⎝ 0.99 ⎠⎦ 15kΩ ⎠⎝ 0.99 ⎠⎦ ⎣⎝ 21kΩ ⎠⎝ 0.99 ⎠⎦ ⎣⎝ ⎣⎝ ⎡⎛ 150kΩ ⎞⎛ 0.99 ⎞⎤ ⎡⎛ 420kΩ ⎞⎛ 0.99 ⎞⎤ ⎡⎛ 100kΩ ⎞⎛ 0.99 ⎞⎤ Avmin = ⎢⎜1+ ⎟⎜ ⎟⎥ ⎢⎜− ⎟⎜ ⎟⎥ ⎢⎜1+ ⎟⎜ ⎟⎥ = −1243 20kΩ ⎠⎝ 1.01 ⎠⎦ 15kΩ ⎠⎝ 1.01 ⎠⎦ ⎣⎝ 21kΩ ⎠⎝ 1.01 ⎠⎦ ⎣⎝ ⎣⎝ Rinmax = 75kΩ(1.01)= 75.8 kΩ Rinnom = RinA = 75 kΩ Rinmin = 75kΩ(0.99) = 74.3 kΩ nom max min Rout = Rout = Rout = RoutC = 0 11.73 (a) C 2 = C = 0.005µF | C1 = 2C = 0.01µF | R = 1 For Q = (b) For f 2 o : Av (s) = 1 2ωO C = 1 2 (40000π )0.005µF = 1.13 kΩ 1 ω 2o | A 0 = 1 | A j ω = → ω H = ω o! | f H = 20 kHz ( ) ( ) o s2 + 2ω o s + ω 2o 2 = 40kHz : C ' → C : C1' = 0.005 µF | C2' = 0.0025 µF | R = 1.13 kΩ 2 11.74 (a) r1=1130; r2=1130; c1=1e-8; c2=5e-9; wo=1/sqrt(r1*r2*c1*c2) n=wo*wo; d=[1 2/(r1*c1) wo*wo]; bode(n,d) 0 Gain dB -10 -20 -30 -40 10 4 10 5 Frequency (rad/sec) 10 6 0 Phase deg -50 -100 -150 -200 10 4 10 5 Frequency (rad/sec) 10 6 11-19 (b) *PROBLEM 11.74 - Low-pass Filter R_R1 $N_0002 $N_0001 1.13k C_C1 $N_0002 $N_0003 0.01UF V_V1 $N_0004 0 18V V_V2 0 $N_0005 18V R_R2 $N_0006 $N_0002 1.13k V_VS $N_0006 0 DC 0V AC 1V C_C2 0 $N_0001 0.005UF X_U1 $N_0001 $N_0003 $N_0004 $N_0005 $N_0003 uA741 .AC DEC 40 1 1MEG .PRINT AC IM(VS) IP(VS) VDB(6) VP(6) .PROBE I(VS) V(6) .END 1 -0d 2 20 -100d 0 -200d -20 -300d >> (c) The magnitude response is very similar to the ideal case. However, note bumps in the phase plot and the excess phase shift as one approaches the fT of the amplifier. In this case, it is not causing a problem, but for higher gain filters the situation would be different. See Probs. 11.82 & 11.84. 11-20 11.75 Using Eq. 11.47 : V1 (s)= G1VS (s)(sC2 + G2 ) | IS = G1 (VS − V1 ) s 2C1C2 + sC2 (G1 + G2 )+ G1G2 ⎛ ⎞ G1(sC2 + G2 ) s 2C1C2 + sC2G2 ⎟ = G1VS 2 IS = G1VS ⎜⎜1− 2 ⎟ s C1C2 + sC2 (G1 + G2 )+ G1G2 ⎝ s C1C2 + sC2 (G1 + G2 )+ G1G2 ⎠ s C1C2 + sC2 (G1 + G2 )+ G1G2 V ZS (s)= S = R1 = R1 IS s2C1C2 + sC2G2 2 s2 + s ωo Q + ω 2o ⎛ 1 ⎞ s⎜ s + ⎟ R2C1 ⎠ ⎝ 1 ωo 1 ⎛ 1 1 ⎞ | = ⎜ + ⎟ Q C1 ⎝ R1 R2 ⎠ R1 R2C1C2 ω 2o = 11.76 r1=2260; r2=2260; c1=2e-8; c2=1e-8; wsq=1/(r1*r2*c1*c2); n=r1*[1 2/(r1*c1) wsq]; d=[1 1/(r1*c1) 0]; bode(n,d) 200 Gain dB 150 100 50 0 10 -1 10 0 10 1 10 2 10 3 Frequency (rad/sec) 10 4 10 5 10 6 -1 10 0 10 1 10 2 10 3 Frequency (rad/sec) 10 4 10 5 10 6 0 Phase deg -50 -100 -150 -200 10 11-21 11.77 G1VS = (sC1 + G1 + G2 )V1 − s(KC1 + G2 )V2 0 = −G2 V1 + (sC2 + G2 )V2 VO = KV2 | ωo = VO K = 2 VS s R1 R2C1C2 + s R1C1 (1− K )+ C2 (R1 + R2 ) + 1 1 [ | Q= R1 R2C1C2 ] ω 3o ⎡ ⎤ 1 ⎢1− K + ⎥ ⎢ R2C2 ⎥ R R C 1 2 1⎦ ⎣ ( For R1 = R2 = R and C1 = C2 = C, ω o = ) 1 RC 11.78 ωo = 1 R1R2C1C2 SRω1o = − | SRω1o = R1 ∂ω o R1 = ω o ∂R1 ω o Q= ω 2o 3− K SKQ = K 3− K 3 ⎛ 1⎞ 1 R ⎛ 1 ωo ⎞ 1 − ⎜− ⎟(R1 ) 2 = 1 ⎜ − ⎟=− 2 ω o ⎝ 2 R1 ⎠ R2C1C2 ⎝ 2 ⎠ 1 1 | By symmetry, SCω1o = − 2 2 11.79 For C1 = C = C2 : ω o = SQω o = 1 C R1R2 | Q= 1 R2 1 | ωo = 2 R1 2R1CQ Q ∂ω o Q ⎛ 1 ⎞ Q ⎛ ωo ⎞ ω = ⎟= ⎜− ⎜ − ⎟ = −1 | SQ o = −1 ω o ∂Q ω o ⎝ 2R1CQ 2 ⎠ ω o ⎝ Q ⎠ 11.80 As noted in Design Example 11.8, the maximally flat response corresponds to Q = 1 2 . ω 2o 1 : AV (s)= 2 | A(0)= 1 | A(jω o ) = → ω H = ω o | ∴ f H = 1 kHz For Q = 2 s + 2ω o s + ω o 2 2 1 R1 = R = R2 and C1 = 2C2 = 2C yields Q = RC = 1 2π 2 (1000) 1 2 | ωo = 1 2R2C 2 = 1 2RC = 1.125 x 10−4 | For C = 0.001 µF, R = 112.5 kΩ. The nearest 5% value is 110 kΩ. The nearest 1% value is 113 kΩ. Using 1% values, C1 = 0.002 µF | C2 = 0.001 µF | R1 = R2 = 113 kΩ 11-22 11.81 Using the R1 = R2 = R and C1 = C2 = C case, A HP (s) = K ωo = 1 RC | Q= 1 3−K | Q =1→ K = 2 s2 s2 + s | A HP (s) = 2 ωo Q + +ω o2 s2 s2 + sω o + +ω o2 We need to find the relationship between ω L and ω o . ω L2 2 =2 2 (ω 2 o −ω ) + (ω ω ) 2 2 L 2 L → ω o4 − 2ω o2ω L2 + ω L4 + ω o2ω L2 = 2ω L4 | ω L4 + ω o2ω L2 − ω o4 = 0 o −ω o2 ± ω o4 + 4ω o4 5 −1 → ω L2 = ω o2 | ω L = 0.7862ω o | 2π (20kHz) = 0.7862ω o 2 2 1 ω o = 1.599x10 5 | RC = = 6.256x10−6 | For C = 270 pF, R = 23.17 kΩ ω L2 = ωo The nearest 1% resistor value is 23.2 kΩ. Final design : C1 = C2 = 270 pF | R1 = R2 = 23.2 kΩ 11.82 1 (a) Q = 2 BW = 1 200kΩ 10 R2 = = Rth 2 1kΩ 2 fo = 7.23 kHz Q Av (f o ) = | fo = 1 ( 2π 10 2x10 3 5 )(2.2x10 ) −10 2 = 51.2 kHz 1 R2 = 100 or 40 dB 2 Rth 3.3kΩ = 3.3 | Rth = 3.3(1kΩ) = 3.3 kΩ | R2 = 3.3(200kΩ)= 660 kΩ 1kΩ 220 pF = 66.7 pF C1 = C2 = 3.3 2f 220 pF (c) KF = f o = 2 | C1 = C2 = 2 = 110 pF | Rth = 1 kΩ | R2 = 200 kΩ o (b) K M = 11-23 11.83 (a) BW = f o 1000Hz 1 R2 R = = 200 Hz | C1 = C2 = C | Q = = 5 → 2 = 100 Q Rth 5 2 Rth Choose Rth = 1 kΩ → R2 = 100 kΩ | C = ωo = ωo 1 1 = = 0.0159 µF Rth R2 2π (10 3 )(10 4 ) 1 : Checking the nearest standard values : 10Rth C C = 0.015 µF → R th = 1.06kΩ - not good; C = 0.01 µF → Rth = 1.6 kΩ | R2 = 160 kΩ Choose R1 = 1.6 kΩ with R3 = ∞. (b) C ' = 11-24 C = 0.004 µF | R1 = 1.6 kΩ | R2 = 160 kΩ | R3 = ∞ 2.25 11.84 (a) r1=1000; r2=2e5; c=2.2e-10; wo=1/sqrt(r1*r2*c*c); q=sqrt(r2/r1)/2; n=[-2*q*wo 0]; d=[1 wo/q wo*wo]; w=logspace(4,7,300); bode(n,d,w) 40 Gain dB 30 20 10 0 -10 10 4 10 5 10 5 10 6 Frequency (rad/sec) 10 7 -50 Phase deg -100 -150 -200 -250 -300 10 4 10 6 10 7 Frequency (rad/sec) (b) SPICE Simulation Results 1 40 2 0d 0 -200d -40 >> -400d SPICE yields: fo = 38.9 kHz, Q = 8.1, Center frequency gain = 38.8 dB. These values are off due to the finite bandwidth of the op-amp and its excess phase shift at the center frequency of the filter. The center frequency is substantially shifted. 11-25 11.85 (a) BW = ωo Q = 1 rad rad | ω L = 0.833 | ω H = 1.167 3 s s 1 rad rad 1 | ω 'o = ω o = 1 | Q' = = 4.65 s s 0.215 1 1 R2 1 C1 = C2 = C : ω o = | Q= | = 2Qω o 2 Rth Rth C C Rth R2 BW ' = BW 2 2 −1 = 0.215 ⎛ ⎞2 ⎞2 ⎞2 ⎛ ⎛ 2 ⎛ Rth ⎞ ⎜ −2Qsω o ⎟ ⎛ Rth ⎞ ⎜ −6s ⎟ ⎜ −6s ⎟ b A s = | For R3 = ∞, ABP (s) = ⎜ ⎟ =⎜ ⎟ ⎜ ( ) BP ( ) ⎜ ⎟ ⎜ ⎟ s ⎟ ⎝ R1 ⎠ ⎜⎜ s2 + s ω o + 1⎟⎟ ⎝ R1 ⎠ ⎜ s 2 + s + 1⎟ ⎜ s 2 + + 1⎟ ⎝ ⎝ Q 3 ⎠ 3 ⎠ ⎝ ⎠ 2 11.86 n=conv([-6 0],[-6,0]); d=conv([1 1/3 1],[1 1/3 1]); bode(n,d) 60 50 Gain dB 40 30 20 10 0 -10 10 -1 10 0 Frequency (rad/sec) 10 1 -1 10 0 Frequency (rad/sec) 10 200 150 Phase deg 100 50 0 -50 -100 -150 -200 10 11-26 1 11.87 Using normalized frequency and R3 = ∞ : 5 kHz → ω o = 1 and 6 kHz → ω o = 1.1 ⎛ −10s ⎞⎛ ⎞ −12s 120s 2 ABP (s) = ⎜ 2 ⎟⎜ ⎟= ⎝ s + 0.2s + 1⎠⎝ s 2 + 0.24s + 1.44 ⎠ s 4 + 0.44s3 + 2.484s2 + 0.528s + 1.44 At the new center frequency s = jω o , − 0.44ω 3o + 0.528ω o = 0 → ω o = 1.095 and A(jω o ) = 1429 = 63.1 dB The bandwidth points can be found using MATLAB: w=linspace(.9,1.5,250); [m,p,w]=bode([120 0 0],[1 .44 2.484 .528 1.44],w); 20*log10(max(m)) ans = 63.098 ((20*log10(a))>60.098).*(w.'); From this last vector one can easily find: ωo = 1.095 or fo = 5.48 kHz, ωL = 0.970 or fo = 4.85 kHz, ωH = 1.237 or fo = 6.19 kHz, BW = 1.34 kHz, Q = 4.09 11-27 11.88 w1=2*pi*5000; q1=5; w2=2*pi*6000; q2=5; n1=[-2*q1*w1 0]; d1=[1 w1/q1 w1*w1]; n2=[-2*q2*w2 0]; d2=[1 w2/q2 w2*w2]; n=conv(n1,n2); d=conv(d1,d2); w=logspace(4,5,100); bode(n,d,w) 70 60 Gain dB 50 40 30 20 10 0 10 4 Frequency (rad/sec) 10 5 200 150 Phase deg 100 50 0 -50 -100 -150 -200 10 4 Frequency (rad/sec) 10 5 11.89 Using ABP = 20 dB at the center frequency : Rin = R1 = 10 kΩ | 10 = KQ = R2 = 100 kΩ | K = 10 1 1 = 2 | R = KR1 = 20 kΩ | C = = = 0.0133 µF. ω o R 2π (600Hz)20kΩ Q 11.90 Q is independent of C in the Tow-Thomas biquad. 11-28 R2 R1 SQ C = 0. 11.91 vO T/2 T 3T/2 2T 0 t -5 V 11.92 The waveform going into the low - pass filter is the same as that in Prob. 11.91 ⎛ 8.2kΩ ⎞ except the amplitude will be VM = 1V ⎜− ⎟ = −3.037 V. ⎝ 2.7kΩ ⎠ 1T ⎛ 10kΩ ⎞ 2 2 (−3.037) The average value of the waveform is V = ⎜ − = +0.759 V. ⎟ T ⎝ 10kΩ ⎠ 11.93 The Fourier series converges very rapidly since only the even terms exist for n ≥ 2 and the terms decrease as 1/n2. Thus the RMS value will be dominated by the first term (n = 1). ⎛ ω ⎞2 π 1 ω 120π 2 Require : ≤ 0.01 | 50 π ≤ 1+ | ω ≥ = = 2.40 Hz ( ) ⎜ ⎟ o 2 157 157 ⎝ωo ⎠ ⎛ ω ⎞2 1+ ⎜ ⎟ ⎝ωo ⎠ 11.94 vO 0.5 V t 0 T/2 0 11.95 T 3T/2 2T vO 1.0 V t 0 0 T/2 T 3T/2 2T 11-29 11.96 *Figure P11.94 - RECTIFIER VS 1 0 PWL(0 0 1M 1 3M -1 5M 1 7M -1 8M 0) R1 1 2 10K R2 4 5 10K R3 5 6 10K R4 2 4 10K R5 1 5 20K D1 3 2 DIODE D2 4 3 DIODE EOP1 3 0 0 2 1E5 EOP2 6 0 0 5 1E5 .MODEL DIODE D IS=1E-12A .TRAN .01M 8M .PRINT TRAN V(6) .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 11.97 *Figure P11.95 - RECTIFIER VS 1 0 PWL(0 0 1M 1 3M -1 5M 1 7M -1 8M 0) R1 0 2 10K R2 4 5 10K R3 5 6 20K R4 2 4 10K D1 3 2 DIODE D2 4 3 DIODE EOP1 3 0 1 2 1E5 EOP2 6 0 1 5 1E5 .MODEL DIODE D IS=1E-12A .TRAN .01M 8M .PRINT TRAN V(6) .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END 11.98 −V V V V1 = I S exp o1 | VO1 = −VT ln 41 | VO 2 = −VT ln 42 10kΩ VT 10 I S 10 I S ⎛ V V ⎞ VV VO3 = −(VO1 + VO2 )= VT ⎜ ln 41 + ln 42 ⎟ = VT ln 18 2 2 10 I S ⎠ 10 I S ⎝ 10 I S ⎛ VV ⎞ VV V VO = −10 4 I D = −10 4 I S exp D = −10 4 I S exp⎜ ln 18 2 2 ⎟ = − 14 2 VT 10 I S ⎝ 10 I S ⎠ 11-30 11.99 Simplify the circuit by taking a Thevenin equivalent of the 5V source and two 10kΩ 10kΩ resistors : VTH = 5V = 2.5V | RTH = 10kΩ 10kΩ = 5kΩ 10kΩ + 10kΩ 100kΩ 5kΩ +5 = 2.62V VO = 5V − Using superposition : V+ = 2.5 100kΩ + 5kΩ 100kΩ + 5kΩ 100kΩ = 2.38V VN = 2.62 − 2.38 = 0.24V VO = 0V : V+ = 2.5 100kΩ + 5kΩ 11.100 4.3kΩ = −0.993 V 4.3kΩ + 39kΩ 4.3kΩ = 0.993 V VO = 10V : V+ = 10 4.3kΩ + 39kΩ VN = 0.993 − (−0.993)= 1.99 V VO = −10V : V+ = −10 11.101 4.3kΩ = 0.487 V 4.3kΩ + 39kΩ 4.3kΩ For VO = −4.3 − 0.6 = −4.9V : V+ = −4.9 = −0.487 V 4.3kΩ + 39kΩ VN = 0.487 − (−0.487) = 0.974 V For VO = 4.3 + 0.6 = 4.9V : V+ = 4.9 11.102 R4 R2 R2 +5 V +5 V + +5 V v VTH O R3 + R TH O R R C v C 11-31 For VO = 0 : V+ = VTH 0.05 R2 R4 = 1− = 0.975V | RTH = R3 R4 | VTH = 5 2 RTH + R2 R3 + R4 For VO = 5 : V+ = VTH RTH 0.05 R2 +5 = 1+ = 1.025V 2 RTH + R2 RTH + R2 Subtracting : 5 RTH R RTH = 0.05V → = 0.01 → 2 = 99 RTH + R2 RTH + R2 RTH R2 97.5 R RTH + R2 0.975 = → VTH 2 = 97.5 → VTH = = 0.985V RTH 0.01 99 RTH RTH + R2 VTH 0.985 = 5 R R4 → 3 = 4.077 | Choosing R4 = 2kΩ → R3 = 8.154kΩ R3 + R4 R4 RTH = 8.154kΩ 2kΩ = 1.606kΩ | R2 = 99(1.606kΩ) = 159kΩ Choosing standard values : R2 = 160 kΩ | R3 = 8.2kΩ | R4 = 2 kΩ 11.103 24kΩ 3.4kΩ + 12 = 6.74 V 3.4kΩ + 24kΩ 3.4kΩ + 24kΩ 24kΩ For vO = 0V : V+ = 6 = 5.26 V 3.4kΩ + 24kΩ ⎛ t ⎞ v (t )= VF − (VF − VI )exp⎜ − ⎟ ⎝ RC ⎠ ⎛ T ⎞ 6.74 = 50.7 µs 6.74 = 12 − (12 − 5.26)exp⎜− 1 ⎟ → T1 = 6200 3.3x10−8 ln 5.26 ⎝ RC ⎠ ⎛ T ⎞ 6.74 5.26 = 0 − (0 − 6.74)exp⎜− 2 ⎟ → T2 = 6200 3.3x10−8 ln = 50.7 µs 5.26 ⎝ RC ⎠ For vO = +12V : V+ = 6 ( ( f = ) ) 1 = 9.86 kHz 50.7µs + 50.7µs 11.104 f = 0. The circuit does not oscillate. VO = 0 is a stable state. 11-32 11.105 R1 1 1+β = | T = 2RC ln = 2RC ln 3 = 2.197RC R1 + R2 2 1− β During steady - state oscillation, the maximum output current from the op- amp is (a) Let R1 = R2 | β= 5 − (−2.5) 5 5 7.5 + | Let R = R1 = R2 | + ≤ 1mA → R ≥ 10kΩ R1 + R2 2R R R 0.001s = 4.55x10−4 s | Selecting C = 0.015µF, R = 30.3kΩ → 30 kΩ (5% values) RC = 2.197 1 Final values : R = R1 = R2 = 30 kΩ | C = 0.015 µF | f = = 1.01 kHz 2.197(30 kΩ)(0.015µF ) 1 1 1 (b) β = R | β max = 30kΩ 0.95 = 0.525 | β min = 30kΩ 1.05 = 0.475 ( ) ( ) 1+ 2 1+ 1+ R1 30kΩ(1.05) 30kΩ(0.95) I= 1+ 0.525 = 1.213x10−3 s → f min = 825 Hz 1− 0.525 1+ 0.475 = 7.949x10−4 s → f min = 1.26 kHz Tmin = 2(30kΩ)(0.95)(0.015µF )(0.90)ln 1− 0.475 4.75 = 2.375V (c ) For vO = +4.75V : V+ = 4.75β = 2 −5.25 For vO = -5.25V : V+ = −5.25β = = −2.625V 2 ⎛ t ⎞ v (t ) = VF − (VF − VI )exp⎜ − ⎟ ⎝ RC ⎠ ⎛ T ⎞ 7.375 = 1.133RC 2.375 = 4.75 − (4.75 − (−2.625))exp⎜ − 1 ⎟ → T1 = RC ln ⎝ RC ⎠ 2.375 ⎛ T ⎞ 7.625 −2.625 = −5.25 − (−5.25 − 2.375)exp⎜ − 2 ⎟ → T2 = RC ln = 1.066RC ⎝ RC ⎠ 2.625 Tmax = 2(30kΩ)(1.05)(0.015µF )(1.1)ln T = 2.199RC = 2.199(30kΩ)(0.015µF ) = 9.896x10 -4 s → f = 1.01 kHz − Very little change 11-33 11.106 For a triangular waverform with peak amplitude VS and ω o = 2000π : ∞ 8VS nπ sin sin nω ot 2 2 2 n=1 n π v (t )= ∑ For the low - pass filter : Av (s)= − 1 1+ s 3000π | Av ( jf ) = 1 ⎛ f ⎞2 1+ ⎜ ⎟ ⎝ 1500 ⎠ Av (j1000) = 0.832 | Av (j3000) = 0.447 | Av (j5000) = 0.287 8VS 1 5 2 π = 7.41 V 0.832 8 π This series contains only odd harmonics : For n = 2, V2000 = 0. ⎛ 5 ⎞1 For f = 3 kHz, n = 3 : V3000 = 0.447⎜ ⎟ = 0.298 V ⎝ .832 ⎠ 32 ⎛ 5 ⎞1 For f = 5 kHz, n = 5 : V5000 = 0.287⎜ ⎟ = 69.0 mV ⎝ .832 ⎠ 52 For a 5 - V fundamental : 2 0.832 = 5 → VS = 11.107 Von VCC T = RC ln 1− β 1+ VCC VEE Tr = RC ln V 1− on VEE 1+ β 11-34 0.6 10 = 841 µs (51kΩ)(0.033µF )ln 1− 0.357 ⎛ 10 ⎞ 1+ 0.357⎜ ⎟ ⎝ 10 ⎠ = (51kΩ)(0.033µF )ln = 416 µs 0.6 1− 10 15kΩ | β= = 0.357 | 15kΩ + 27kΩ 1+ 11.108 VCC V V 1+ on 1+ β CC VEE VCC T VEE | Tr = RC ln | ln = ln Von V 1− β Tr 1− 1− on VEE VEE ⎛5⎞ 0.6 1+ β ⎜ ⎟ 1+ ⎛ 1.12 ⎞ ⎛ 1.12 ⎞ ⎛1+ β ⎞ 2 10µs 1+ β ⎝5⎠ 5 ln = ln | ln⎜ | ⎜ ⎟ ⎟ = 2ln ⎟=⎜ 0.6 ⎝ ⎠ 1− 1− 1− β β 0.88 β 0.88 5µs ⎝ ⎠ ⎝ ⎠ 1− 5 R MATLAB gives β = 0.6998 → 1 = 2.33 | R2 = 13 kΩ | R2 = 30.3kΩ → 30 kΩ R2 Von VCC T = RC ln 1− β 1+ 1+ β 10−5 = 7.595µs | C =150 pF | R = 50.6kΩ → 51 kΩ RC = 0.6 1+ 5 ln 1− 0.6998 11-35 CHAPTER 12 12.1 86 (a) A = 10 20 = 2.00x104 | Av-ideal = 1+ A Av = = 1+ Aβ FGE = 150kΩ = 13.5 12kΩ 2.00x10 4 = 13.49 ⎛ ⎞ 4 12kΩ 1+ 2.00x10 ⎜ ⎟ ⎝162kΩ ⎠ 1 13.5 −13.49 = 6.75x10−4 or 0.0675% | Note : FGE ≅ = 6.75x10−4 Aβ 13.5 150kΩ (b) Av-ideal = 1+ 1.2kΩ = 126 | Av = 2.00x10 4 = 125 ⎛ 1.2kΩ ⎞ 4 1+ 2.00x10 ⎜ ⎟ ⎝ 151.2kΩ ⎠ ⎛ 1.2kΩ ⎞ 1 = 6.30x10−3 Aβ = 2.00x10 4 ⎜ ⎟ = 159 >> 1 | FGE ≅ A 151.2kΩ β ⎝ ⎠ 12.2 (a) A = 10 100 20 = 105 | Av-ideal = 1+ 47kΩ = 9.393 5.6kΩ 105 = 9.392 ⎛ ⎞ 5 5.6kΩ 1+ 10 ⎜ ⎟ ⎝ 52.6kΩ ⎠ 1⎛ 1 ⎞ 1 −4 GE = ⎜ FGE = = 9.39x10−5 ⎟ = 8.82x10 1+ Aβ β ⎝1+ Aβ ⎠ Av = A = 1+ Aβ 94 (b) A = 10 20 = 5.01x104 | Av-ideal = 1+ 47kΩ = 9.393 5.6kΩ 5.01x10 4 = 9.391 ⎛ ⎞ 4 5.6kΩ 1+ 5.01x10 ⎜ ⎟ ⎝ 52.6kΩ ⎠ 1⎛ 1 ⎞ 1 −3 GE = ⎜ FGE = = 1.87x10−4 ⎟ = 1.76x10 β ⎝1+ Aβ ⎠ 1+ Aβ A Av = = 1+ Aβ 12-1 12.3 92 220kΩ = −10 22kΩ ⎡ ⎛ 22kΩ ⎞ ⎤ 3.98x10 4 ⎜ ⎢ ⎟ ⎥ R2 ⎛ Aβ ⎞ ⎝ 242kΩ ⎠ ⎥ ⎢ Av = − ⎜ = −9.997 ⎟ = −10 ⎞⎥ ⎛ ⎢ R1 ⎝1+ Aβ ⎠ 4 22kΩ ⎟⎥ ⎢1+ 3.98x10 ⎜ ⎝ 242kΩ ⎠⎦ ⎣ (a) A = 10 20 = 3.98x104 | Av-ideal = − 1 10 − 9.997 = 2.76x10−4 or 0.0276% | Note : FGE ≅ = 2.76x10−4 Aβ 10 ⎡ ⎛ 1.1kΩ ⎞ ⎤ 3.98x10 4 ⎜ ⎢ ⎟ ⎥ 220kΩ R2 ⎛ Aβ ⎞ ⎝ 221.1kΩ ⎠ ⎥ ⎢ = −199.0 (b) Av-ideal = − 1.1kΩ = −200 | Av = − R ⎜⎝1+ Aβ ⎟⎠ = −200 ⎢ ⎛ 1.1kΩ ⎞ ⎥ 4 1 ⎢1+ 3.98x10 ⎜ 221.1kΩ ⎟ ⎥ ⎠⎦ ⎝ ⎣ ⎛ 1.1kΩ ⎞ 1 = 5.05x10−3 Aβ = 3.98x10 4 ⎜ ⎟ = 198 >> 1 | FGE ≅ A β 221.1kΩ ⎠ ⎝ FGE = 12.4 94 20 47kΩ = −10 4.7kΩ ⎡ ⎛ 4.7kΩ ⎞ ⎤ 5.01x10 4 ⎜ ⎢ ⎟ ⎥ R2 ⎛ Aβ ⎞ ⎝ 51.7kΩ ⎠ ⎥ ⎢ = −9.998 Av = − ⎜ ⎟ = −10 ⎛ ⎞⎥ ⎢ R1 ⎝1+ Aβ ⎠ 4 4.7kΩ ⎟⎥ ⎢1+ 5.01x10 ⎜ ⎝ 51.7kΩ ⎠⎦ ⎣ R ⎛ 1 ⎞ 1 −10 GE = − 2 ⎜ = -2.20x10-3 | FGE = = 2.20x10−4 ⎟= ⎛ ⎞ 1+ Aβ R1 ⎝1+ Aβ ⎠ 4.7kΩ 1+ 5.01x10 4 ⎜ ⎟ ⎝ 51.7kΩ ⎠ (a) A = 10 100 = 5.01x10 4 | Av-ideal = − 47kΩ = −10 4.7kΩ ⎡ ⎛ 4.7kΩ ⎞ ⎤ 105 ⎜ ⎢ ⎟ ⎥ R2 ⎛ Aβ ⎞ ⎝ 51.7kΩ ⎠ ⎥ ⎢ = −9.999 Av = − ⎜ ⎟ = −10 ⎛ ⎞⎥ ⎢ R1 ⎝1+ Aβ ⎠ 5 4.7kΩ ⎢1+ 10 ⎜ 51.7kΩ ⎟⎥ ⎝ ⎠⎦ ⎣ R ⎛ 1 ⎞ 1 −10 GE = − 2 ⎜ = -1.10x10-3 | FGE = = 1.10x10−4 ⎟= ⎛ 4.7kΩ ⎞ R1 ⎝1+ Aβ ⎠ 1+ Aβ 1+ 105 ⎜ ⎟ ⎝ 51.7kΩ ⎠ (b) A = 10 20 = 105 | Av-ideal = − 12-2 12.5 46 ACL = 10 20 = 200 → FGE ≅ R2 = 200 | β ≅ R1 1 1 = R 201 1+ 2 R1 1 201 < 0.001 | A > = 2.01x105 or 106 dB Aβ 0.001 12.6 FGE = 1− 1 A = ≤ 10−4 requires A ≥ 10,000 (80 dB) 1+ A 1+ A 12.7 32 1 1 = Av = 10 20 = 39.8 | FGE ≅ < 0.002 Aβ β 12.8 Av = 1+ R2 R1 Avmin = 1+ | Avnom = 1+ | A> 39.8 = 1.99x10 4 or 86 dB 0.002 99R1 (1+ 0.0001) 99R1 = 100 | Avmax = 1+ = 100.02 R1 R1(1− 0.0001) 99R1 (1− 0.0001) R1 (1+ 0.0001) = 98.98 | 1 < .0001 | A > 106 or 120 dB Aβ 12.9 Driving the output of the circuit in Fig. 12.3 with a current source of value iX: vX v − Av id iX = iO + i2 | i2 = ; iO = X ; v id = −i 2 R1 R1 + R2 RO 1+ Aβ v + Ai 2 R1 R1 iO = X = vX where β = RO RO R1 + R2 1+ Aβ vX v RO i X = vX + and R out = X = (R1 + R2 ) RO R1 + R2 i X 1+ Aβ 12.10 Assuming i− << i2 : i1 ≅ i2 = β= R1 1 vX = | i− = −i X = − =− R1 + R2 48 Rid (1+ Aβ ) 0.1V (1+ 47) vO = = 100 µA and i− << i 2 R1 + R2 48kΩ 0.1V = −48.0 pA ⎛ ⎞ 6 5 1 10 Ω⎜1+ 10 ⎟ 48 ⎠ ⎝ 12-3 12.11 86 (a) A = 10 20 = 2.00x104 ⎛ 12kΩ ⎞ | 1+ Aβ = 1+ 2.00x10 4 ⎜ ⎟ = 1482 ⎝ 162kΩ ⎠ A 2.00x10 4 = = 13.49 | Rin = 250kΩ(1+ Aβ ) = 371 MΩ 1482 1+ Aβ 250Ω 150kΩ = = 169 mΩ | Note that Av-ideal = 1+ = 13.5 12kΩ (1+ Aβ ) Av = Rout (b) A v-ideal = 1+ Av = ⎛ 1.2kΩ ⎞ 150kΩ = 126 | 1+ Aβ = 1+ 2.00x10 4 ⎜ ⎟ = 159.7 1.2kΩ ⎝ 151.2kΩ ⎠ A 2.00x10 4 250Ω = = 124 | Rin = 250kΩ(1+ Aβ ) = 39.9 MΩ | Rout = = 156 Ω 160.7 1+ Aβ (1+ Aβ ) 12.12 (a) A = 10 100 20 = 105 ⎛ ⎞ 5.6kΩ | 1+ Aβ = 1+ 105 ⎜ ⎟ = 10647 ⎝ 5.6kΩ + 47kΩ ⎠ A 105 = = 9.392 | Rin = 400kΩ(1+ Aβ )= 10.6 MΩ 1+ Aβ 10647 200Ω 47kΩ = = 18.8 mΩ | Note that Av-ideal = 1+ = 9.393 5.6kΩ (1+ Aβ ) Av = Rout (b) A = 10 = 5.01x10 4 ⎛ ⎞ 5.6kΩ | 1+ Aβ = 1+ 5.01x10 4⎜ ⎟ = 5335 ⎝ 5.6kΩ + 47kΩ ⎠ A 5.01x10 4 = = 9.391 | Rin = 400kΩ(1+ Aβ )= 2.13 MΩ 1+ Aβ 5335 200Ω 47kΩ = = 37.5 mΩ | Note that Av-ideal = 1+ = 9.393 5.6kΩ (1+ Aβ ) Av = Rout 94 20 12-4 12.13 100 (a) A = 10 20 = 105 ⎛ ⎞ 5.6kΩ 47kΩ | 1+ Aβ = 1+ 105⎜ = −8.393 ⎟ = 10647 | Av-ideal = − 5.6kΩ ⎝ 5.6kΩ + 47kΩ ⎠ Av = − R2 R2 ⎛ Aβ ⎞ 10646 = −8.392 | Rin = R1 + Rid = 5.60 kΩ ⎜ ⎟ = −8.393 R1 ⎝1+ Aβ ⎠ 1+ A 10647 Rout = 200Ω = 18.8 mΩ (1+ Aβ ) 94 20 (b) A = 10 = 5.01x10 4 ⎛ ⎞ 5.6kΩ | 1+ Aβ = 1+ 5.01x10 4⎜ ⎟ = 5335 ⎝ 5.6kΩ + 47kΩ ⎠ Av = − R2 R2 ⎛ Aβ ⎞ 5334 = −8.391 | Rin = R1 + Rid = 5.60 kΩ ⎜ ⎟ = −8.393 R1 ⎝1+ Aβ ⎠ 1+ A 5335 Rout = 200Ω = 37.5 mΩ (1+ Aβ ) 12.14 (a) A = 10 94 20 = 5.01x10 4 ⎛ ⎞ 4.7kΩ 47kΩ | 1+ Aβ = 1+ 5.01x10 4 ⎜ = −10 ⎟ = 4555 | Av-ideal = − 4.7kΩ ⎝ 4.7kΩ + 47kΩ ⎠ Av = − R2 R2 ⎛ Aβ ⎞ 4554 = −9.998 | Rin = R1 + Rid = 4.70 kΩ ⎜ ⎟ = −10 R1 ⎝1+ Aβ ⎠ 1+ A 4555 Rout = 100Ω = 21.6 mΩ (1+ Aβ ) 100 (b) A = 10 20 = 105 ⎛ ⎞ 4.7kΩ 47kΩ | 1+ Aβ = 1+ 105 ⎜ = −10 ⎟ = 9092 | Av-ideal = − 4.7kΩ ⎝ 4.7kΩ + 47kΩ ⎠ Av = − R2 R2 ⎛ Aβ ⎞ 9091 = −9.999 | Rin = R1 + Rid = 4.70 kΩ ⎜ ⎟ = −10 R1 ⎝1+ Aβ ⎠ 1+ A 9092 Rout = 100Ω = 11.0 mΩ (1+ Aβ ) 12.15 ⎛ ⎞ 2R1 Setting v2 = 0, Rin1 = Rid (1+ Aβ )= (500kΩ)⎜1+ 4x10 4 ⎟ = 785 MΩ 2R1 + 49R1 ⎠ ⎝ RO 75 By symmetry, Rin2 = Rin1 = 785 MΩ | Rout = Rout3 = = = 3.75 mΩ ⎛ (1+ Aβ ) ⎜1+ 4x104 ⎞⎟ 2 ⎠ ⎝ 12-5 12.16 Op-amp parameters: Rid = 500 kΩ, Ro = 35 Ω, A = 50,000 Amplifier Requirements: AV = 200, Rin ≥ 200 MΩ, Rout ≤ 0.2 Ω. We must immediately discard the inverting amplifier case. Rin = R1 requires R1 ≥ 200 MΩ which can be achieved, but then R2 must be 200 R1 ≥ 40 GΩ which is out of the question (see values in Appendix A). So, working with the non-inverting amplifier: Av = 200 ⇒ β = R out = R1 1 50000 = and Aβ = = 250 >> 1 R1 + R2 200 200 Ro 35 ≅ = 0.14Ω meets the specification 1+ Aβ 250 R in = Rid (1+ Aβ )≅ 500kΩ(250)= 125MΩ does not meet the requirements. So the specifications cannot be met using a single-stage amplifier built using the op-amp that was specified in the problem. 12.17 The non-inverting amplifier is the only one that can hope to achieve both the required gain and with such a high value of input resistance: Av = 1 β = 200 and Aβ = 10 4 = 50 200 Rin = Rid (1+ Aβ ) = 1MΩ(51) = 51 MΩ - too small R out = Ro 100Ω = = 1.96Ω - too large (1+ Aβ ) 51 If the gain specification is met, the input and output resistance specifications will not be met. 12.18 ⎛ R2 ⎞⎛ Aβ ⎞ The open-circuit voltage is v th = v s ⎜− ⎟⎜ ⎟ . Checking the loop-gain: ⎝ R1 ⎠⎝ 1+ Aβ ⎠ ⎛ R ⎞ ⎛ ⎞ ⎛110kΩ ⎞ 6.8kΩ Aβ = (5x10 4 )⎜ ⎟ = 2910 >> 1 so v th = v S ⎜− 2 ⎟ = −v S ⎜ ⎟ = −16.2v S ⎝ 6.8kΩ + 110kΩ ⎠ ⎝ 6.8kΩ ⎠ ⎝ R1 ⎠ Rth = Rout = 12-6 Ro R 250Ω ≅ o = = 85.9 mΩ 1+ Aβ Aβ 2910 12.19 A v S . Checking the loop gain : 1+ Aβ ⎛ R2 ⎞ ⎛ ⎞ ⎛ 56kΩ ⎞ 0.39kΩ Aβ = 10 4 ⎜ ⎟ = 69.2 >> 1 so vth ≅ vS ⎜1+ ⎟ = v S ⎜1+ ⎟ = 145 vS ⎝ 0.39kΩ + 56kΩ ⎠ ⎝ 0.39kΩ ⎠ ⎝ R1 ⎠ The open circuit voltage is vth = or more exactly : vth = v S A 10 4 Ro 200Ω = vS = 143 vS | Rth = Rout = = = 2.85 Ω 1+ 69.2 1+ Aβ 70.2 1+ Aβ 12.20 Applying the definintion of fractional gain error: R ⎡ R2 (1± ε)⎤ Aβ ⎥ − 2 − ⎢− ⎡ (1± ε)⎤ Aβ R1 ⎢⎣ R1(1 m ε)⎥⎦ 1+ Aβ Aβ ⎥ FGE = = 1− ⎢ ≅ 1− (1± 2ε) R 1+ Aβ ⎢⎣ (1 m ε)⎥⎦ 1+ Aβ − 2 R1 FGE ≅ 1− Aβ 1 Aβ Aβ m 2ε = m 2ε 1+ Aβ 1+ Aβ 1+ Aβ 1+ Aβ For Aβ >> 1, FGE ≅ 1 m 2ε = Aβ 1 1 2x10 1000 ( 5 ) 106 1 m 2ε which must be ≤ 0.01. A = 10 20 = 2.00x105 Aβ m 2ε ≤ 0.01 | Taking the positive sign, 2ε ≤ 0.005 and ε ≤ 0.25% 12.21 Using the results from Prob. 12.20, 54 Av = 10 20 = 501 | For Aβ = 4x10 4 1 = 79.8 >> 1, so FGE ≅ m 2ε which must be ≤ 0.02 Aβ 501 1 1 m 2ε = m 2ε ≤ 0.02 | Taking the positive sign, 2ε ≤ 0.00747 and ε ≤ 0.374% 79.8 Aβ 12.22 V+ = 3V 99kΩ 3 - 2.722 2.722 − VO = 2.722 V | = 10.1kΩ + 99kΩ 9.9kΩ 101kΩ | VO = −0.111 V | VOideal = 0 V 12-7 12.23 99kΩ 3.95 - 3.675 3.675 − VO = 3.675 V | = | VO = 0.869 V 101kΩ 10.1kΩ + 99kΩ 9.9kΩ For matched resistors, VOideal = −10(V1 − V2 ) = −10(3.95 − 4.05)= +1.00 V V+ = 4.05V ⎛ 1− 0.869 ⎞ ⎟ = 13.1% 1 ⎝ ⎠ ε = 100%⎜ 12.24 v1 + v 2 = 10sin120πt V and v id = v1 − v 2 = 0.50sin5000πt V 2 v − v− v ic − v + 0.09258 99kΩ = 0.90742v ic | i = ic = = v ic (b) v + = v ic 9.9kΩ 10.1kΩ + 99kΩ 9.9kΩ 9.9kΩ 0.09258 v O = v− − i(101kΩ) = v + − i(101kΩ) = 0.90742v ic − v ic (101kΩ) 9.9kΩ v v O = −0.037v ic and Acm = O = −0.037 | The value of Adm = −10 is not v ic (a) v ic = affected by the small tolerances. (c) CMRR = Adm = 270 - a paltry 48.6 dB Acm (d) vO = Admv id + Acmv ic = −0.370sin(120πt ) − 5.00sin(5000πt ) V 12.25 5 + 5.01 = 5.005V. The maximum equivalent input error is 2 5.005 VIC = = 0.500 mV , but the sign is unknown. Therefore the meter reading CMRR 10 4 may be anywhere in the range 9.50 mV ≤ Vmeter ≤ 10.5 mV. VIC = 12-8 12.26 30kΩ 10kΩ = 3.75 V 10kΩ + 30kΩ 20kΩ V + V 11.25 + 3.75 V1 - V2 = 15V = 7.50 V | VCM = 1 2 = = 7.50V. 2 10kΩ + 30kΩ 2 VCM VCM The maximum equivalent input error is . We need < 10−4 (V1 - V2 ) CMRR CMRR 4 10 (7.5V ) CMRR > = 10 4 or 80 dB. 7.5V 10.2kΩ 10kΩ (b) V1 = 15V 20.2kΩ = 7.574 V | V2 = 15V 20.2kΩ = 7.426 V 200Ω V +V = 0.1485 V | VCM = 1 2 = 7.50V. V1 - V2 = 15V 2 20.2kΩ 10 4 (7.5V ) VCM −4 < 10 (V1 - V2 ) or CMRR > = 5.05x105 or 114 dB. We need CMRR 0.1485V (a) V = 15V 10kΩ + 30kΩ = 11.25 V 1 | V2 = 15V 12.27 One worst-case tolerance assignment is given below. The second is found by reversing the pairs of resistor values. i v 9.995 k Ω i 10.005 k Ω v O i c + 10.005 k Ω 9.995 k Ω v −v v − v+ 0.50025 9.995 = 0.49975v ic | i = ic − = ic = v ic 9.995kΩ 9.995kΩ 9.995kΩ 10.005 + 9.995 0.50025 vO = v− − i(10.005kΩ)= v + − i(10.005kΩ)= 0.49975v ic − v ic (10.005kΩ) 9.995kΩ v vO = −0.001vic and Acm = O = −0.001 | The value of Adm = 1 is not affected by the vic v+ = v ic small tolerances. CMRR = Adm = 1000 | CMRRdB = 60 dB Acm 12-9 12.28 ⎛ ⎞ 2kΩ Setting v2 = 0, Rin1 = Rid (1+ Aβ ) 2Ric = (1MΩ)⎜1+ 7.5x10 4 ⎟ 2(500MΩ) = 852 MΩ ⎝ 2kΩ + 24kΩ ⎠ Ro 100 By symmetry, Rin 2 = Rin1 = 852 MΩ | Rout = Rout 3 = = = 2.67 mΩ (1+ Aβ ) ⎛⎜1+ 75000 ⎞⎟ ⎝ 2 ⎠ 12.29 V2 − V3 (4.9kΩ)= 4.500 200Ω 9.99kΩ V −V V4 = V3 − 2 3 (4.9kΩ)= 5.500 | V6 = V4 = 2.7473V 200Ω 10.01kΩ + 9.99kΩ V1 - V5 V −V = 5 O | V5 = V6 | VO = 0.991 V 9.99kΩ 10.01kΩ V −V V - V V −V V4 i1 = - 2 3 - 1 5 = -75.4 µA | i2 = 2 3 = -375 µA 200Ω 9.99kΩ 200Ω 10.01kΩ + 9.99kΩ V −V i3 = 5 O = +175 µA 10.01kΩ The common - mode and differential - mode inputs to the differential subtractor are V +V Vcm = 1 4 = 5V & Vdm = V1 − V4 = −1V with V1 = −0.5V and V4 = +0.5V 2 The subtractor outputs for the common - mode and differential - mode inputs are : V2 = Va = 4.99V | V3 = Vb = 5.01V | V1 = V2 + 9.99kΩ V1 - V5 V5 − VOcm CM : V5 = V6 = 5 = 2.4975V | = | VOcm = −0.0100 V 9.99kΩ 10.01kΩ 10.01kΩ + 9.99kΩ 9.99kΩ V1 - V5 V − V dm = 0.24975V | = 5 O | VOdm = 1.00 V DM : V5 = V6 = 0.5 9.99kΩ 10.01kΩ 10.01kΩ + 9.99kΩ 1.00 −0.01 A Adm = = −50.0 | Acm = = −0.002 | CMRR = dm = 25000 or 88.0 dB Acm −0.02 5 12-10 12.30 V2 − V3 (4.9kΩ)= 3.00V 200Ω V −V 9.99kΩ V4 = V3 − 2 3 (4.9kΩ)= 3.00V | V6 = V4 = 1.4985V 200Ω 10.01kΩ + 9.99kΩ V −V V1 - V5 = 5 O | V5 = V6 | VO = −6.01 mV 9.99kΩ 10.01kΩ V −V V - V V −V V4 i1 = - 2 3 - 1 5 = -150 µA | i2 = 2 3 = -150 µA 200Ω 9.99kΩ 200Ω 10.01kΩ + 9.99kΩ V −V i3 = 5 O = +149 µA 10.01kΩ 3+ 3 VO = Admvid + Acmvic | − 6.01x10−3 = -50(3 − 3)+ Acm | Acm = −2.00x10−3 2 A 50 CMRR = dm = = 2.50x10 4 or 88.0 dB | It has been assumed that −3 Acm 2.00x10 V2 = Va = 3.00V | V3 = Vb = 3.00V | V1 = V2 + the value of Adm is not affected by the small tolerances. See solution to Prob. 12.29. 12.31 ⎛ R⎞ ⎛ R⎞ ⎛ R⎞ VO = (VOS − I B1 R1)⎜1+ 2 ⎟ − I B2 R3 ⎜− 2 ⎟ = (VOS − I B1 R1 )⎜1+ 2 ⎟ + I B 2 R2 ⎝ R3 ⎠ ⎝ R3 ⎠ ⎝ R3 ⎠ ⎛ 106 ⎞ VO = ±0.001−10−7105 ⎜1+ 5 ⎟ + 0.95x10−7106 = ±.011− .015V. Worst case VO = −0.026 V. ⎝ 10 ⎠ ( ) Ideal output = 0 V. Error = -26 mV.Yes, R1 should be R2 R3 = 90.9 kΩ. I B2 1M Ω R 100 k Ω R 1M Ω 2 -I V O 3 + + B2 R + 3 R 100 k Ω R 2 VO 3 + + V I OS B1 R 1 100 k Ω R V 1 OS I B1 R 1 100 k Ω 12-11 12.32 ⎛ R ⎞ ⎛ R ⎞ ⎛ R ⎞ VO = (VOS − IB1R1 )⎜1+ 2 ⎟ − IB 2 R3 ⎜− 2 ⎟ = (VOS − IB1R1 )⎜1+ 2 ⎟ + IB 2 R2 ⎝ R3 ⎠ ⎝ R3 ⎠ ⎝ R3 ⎠ ⎛ 510kΩ ⎞ −7 VO = ±0.01− 2x10−7 (10 5 ) ⎜1+ ⎟ + 2.5x10 (510kΩ) = ±0.061+ 0.0055V ⎝ 100kΩ ⎠ [ ] Worst case VO = +0.066.5 mV. Ideal output = 0 V. Error = 66.5 mV. Yes, R1 should be R2||R3 = 90.9 kΩ. 12.33 vO = Av (vid + VOS ) | Av = dvO 10 − (−5) V = = +7500 dvid 2 − 0 mV When vO = 0, vid = −VOS and so VOS = − 0.667 mV. 12.34 Av 7,500 -6 -4 4 -2 6 2 vid (mV) 12.35 For I B2 = 0 : Since v + must = v- = VOS , the current through C is iC (t ) = VOS R 1 t 1 tV V iC (t ) dt = VOS + ∫0 OS dt = VOS + OS t ∫ 0 R RC C C For VOS = 0, iC (t ) = I B2 since v- = v+ = 0. vO (t )= VOS + vO (t )= 1 C 1 ∫ i (t )dt = C ∫ I B2 t | Summing these two results yields 0 C V I Eq. (11.103) : vO (t ) = VOS + OS t + B2 t | Note that vC (0) = 0 for both cases. RC C 12-12 t 0 C t I B2 dt = 12.36 R R2 or 2 = 99 | For bias current compensation, R1 R2 = 10kΩ R1 R1 R2 1MΩ R1R2 = = 10kΩ | R2 = 10kΩ(1+ 99) = 1.00 MΩ and R1 = = 10.1kΩ R1 + R2 1+ R2 99 R1 The nearest 5% values would be 1 MΩ and 10 kΩ. 40dB = 100 = 1+ 12.37 (a ) Ideal ⎛ 100kΩ ⎞ VO = −0.005V ⎜1+ ⎟ = −0.460V ⎝ 1.1kΩ ⎠ 10 4 = −0.546V 4 1.1kΩ 1+ 10 101.1kΩ (b) V = (−0.005V − 0.001V )1+ Aβ = (−0.005V − 0.001V ) A O (c) Error = -0.460 - (-0.546) = −0.187 or −18.7% -0.460 12.38 Inverting Amplifier : vO = Av v S = −6.2vS as long as v O ≤ 10V as constrained by the op - amp power supply voltages 1 = -6.2V, feedback loop is working and V- = 0 (a) VO = −6.2() (b) VO = −6.2(−3) = +18V; VO saturates at VO = +10V The feedback loop is "broken" since the open - loop gain is now 0. (The output voltage does not change when the input changes so A = 0) 6.2kΩ 1kΩ + 10 = −1.19V By superposition, V− = −3 7.2kΩ 7.2kΩ 12.39 vO 10 V Gain = -6.2 5V vS -2 V -1 V 1V 2V -5 V -10 V 12-13 12.40 Inverting Amplifier : vO = Av v S = −10vS as long as v O ≤ 10V as constrained by the op - amp power supply voltages (a) VO = −10(0.5) = -5.00 V, the feedback loop is working, and V- = 0 (b) VO = −10(1.2) = -12.0V; VO saturates at VO = +10V The feedback loop is "broken" since the open - loop gain is now 0. (The output voltage does not change when the input changes so A = 0) 10kΩ 1kΩ −10 = 0.182 V By superposition, V− = 1.2 11kΩ 11kΩ 12.41 vO 10 V 5V Gain = -10.0 vS -2 V -1 V 1V 2V -5 V -10 V 12.42 Noninverting Amplifier : vO = Av v S = +40vS as long as v O ≤ 15V (a) VO = 40(0.25V ) = +10V, the feedback loop is working, and VID = 0 (b) VO = 40(0.5V ) = 20V; VO saturates at VO = +15V The feedback loop is "broken" since the open - loop gain is now 0. (The output voltage does not change when the input changes so A = 0) 1kΩ = 0.125V. VID = V+ − V− = 0.5V −15 1kΩ + 39kΩ 12-14 12.43 vO 15 V 7.5 V Gain = +40.0 vS -1 V -0.5 V 0.5 V 1V -7.5 V -15 V 12.44 Noninverting Amplifier : vO = Av v S = +43.9vS as long as v O ≤ 15V (a) VO = 43.9(0.25V ) = +11.0V, feedback loop is working, and VID = 0 (b) VO = 43.9(0.5V ) = 22.0V; VO saturates at VO = +15V The feedback loop is "broken" since the open - loop gain is now 0. (The output voltage does not change when the input changes so A = 0) 0.91kΩ = 0.158 V. VID = V+ − V− = 0.5V −15 0.91kΩ + 39kΩ 12-15 12.45 v S i + O i L v O i2 10 k Ω R R 2 1 iO = iL + i2 and iO ≤ 1.5mA. The output voltage requirement gives i L ≤ which leaves 0.500mA as the maximum value of i2 . i2 = The closed - loop gain of 40 db (A v = 100) requires 10V = 1.00mA 10kΩ 10V gives (R1 + R2 )≥ 20kΩ. R1 + R2 R2 = 99. R1 The closest ratio from the resistor tables appears to be R2 = 100 which is within 1% R1 of the desired ratio. (This is close enough since we are using 5% resistors.) There are many many choices that meet both R2 = 100 and (R1 + R2 )≥ 20kΩ. R1 However, the choice, R1 = 200Ω and R 2 = 20kΩ is not acceptable because its minimum value does not meet the requirements : 20.2kΩ(1− 0.05) = 19.2kΩ. The smallest acceptable pair is R1 = 220Ω and R 2 = 22kΩ. 12-16 12.46 R v R 2 1 i 2 S v 5k Ω L R O + i O i L 15V = 3 mA so i 2 ≤ 1 mA 5kΩ v 15 i 2 = O ≤ 1 mA requires R 2 ≥ = 15kΩ .001 R2 i O = i L + i 2 ≤ 4mA and i L = To account for the resistor tolerance, 0.95R2 ≥ 15kΩ requires R 2 ≥ 15.8kΩ . For AV = 46 dB = 200, R2 = 200 R1, and one acceptable resistor pair would be R1 = 1 kΩ and R2 = 20 kΩ. Many acceptable choices exist. An input resistance constraint might set a lower limit on R1. 12.47 The maximum base current is limited to 5 mA, so the maximum emitter current is limited to I E = (β F + 1)I B = 51(5mA)= 255 mA. Since I E = 10V 10V , R≥ = 39.2 Ω. R 255mA 12.48 R v R 2 1 i 2 S v 5k Ω L R O + i O i L 10V 10V = 2.5 mA and iL = = 2 mA so i2 ≤ 0.5 mA 4kΩ 5kΩ 10V R R2 ≥ = 20kΩ Av = 46dB ⇒ 2 = 200 R1 0.5mA iO = iL + i2 ≤ One possible choice would be R2 = 20 kΩ and R1 = 100 Ω. However, the op-amp would not be able to supply enough output current if tolerances are take into account. Better choices would be R2 = 22 kΩ and R1 = 110 Ω or R2 = 200 kΩ and R1 = 1 kΩ which would give the amplifier a much higher input resistance. (b) V = vo max 200 = 10V = 50 mV (c) Rin = R1 = 110 Ω and 1 kΩ for the two designs given above. 200 12.49 12-17 Using the expressions in Table 12.1: ⎛ 105 ⎞ ⎜ 240kΩ 11 ⎟ 24kΩ 1 R2 ⎛ Aβ ⎞ ⎜ ⎟ = −10.0 = | A v1 = − ⎜ First stage : β = ⎟=− 24kΩ ⎜ 105 ⎟ R1 ⎝ 1+ Aβ ⎠ 24kΩ + 240kΩ 11 ⎜1+ ⎟ ⎝ 11 ⎠ ⎛ R2 ⎞ 240kΩ Ro 100 Rin1 = R1 + ⎜ Rid = 24.0 kΩ | Rout1 = = = 11.0 mΩ ⎟ = 24kΩ + 500kΩ 5 1+ Aβ ⎠ 1+ Aβ 1+ 10 105 ⎝ 1+ 11 ⎛ 105 ⎞ 10kΩ 1 50kΩ ⎜ 6 ⎟ ⎟ = −5.00 ⎜ = | Av2 = − Second stage : β = 10kΩ + 50kΩ 6 10kΩ ⎜ 105 ⎟ ⎟ ⎜1+ ⎝ 6 ⎠ Rin2 = 10kΩ + 500kΩ 240kΩ 100 = 10.0 kΩ | Rout2 = = 6.00 mΩ 5 1+ 10 105 1+ 6 Overall amplifier : 10kΩ (−5.00)= +50.0 | Rin = 24.0 kΩ | Rout = 6.00 mΩ 10.0kΩ + 11.0mΩ For all practical purposes, the numbers the same. R out = 6.00 mΩ is a good Av = −10.0 approximation of 0 Ω, and Av = −10.0(−5.00)= +50.0 12.50 Use the expressions in Table 12.1. β1 = 47kΩ A 105 105 = 0.010755 | Av1 = = = = +9.30 47kΩ + 390kΩ 1+ Aβ1 1+ 105 (0.010755) 10756 24kΩ A 105 105 β2 = = 0.19355 | Av1 = = = = +5.17 24kΩ + 100kΩ 1+ Aβ2 1+ 105 (0.19355) 19356 Av = (9.30)(5.17)= 48.1 Rin = Rid1 (1+ Aβ )= 250kΩ(10756)= 2.69 GΩ | Rout = 12-18 Ro2 200 = = 10.3 mΩ 1+ Aβ2 19356 12.51 Use the expressions in Table 12.1. β1 = β2 = Av2 = − 20kΩ 1 A 105 105 = | Av1 = = = = +7.00 20kΩ + 120kΩ 7 1+ Aβ1 1+ 105 7 14287 ( ⎛ 14286 ⎞ R2 ⎛ Aβ2 ⎞ ⎜ ⎟ = −6⎜ ⎟ = −6.00 | R1 ⎝ 1+ Aβ2 ⎠ ⎝ 14287 ⎠ ) Av = (7.00)(−6.00) = −42.0 Rin = Rid1 (1+ Aβ1 )= 250kΩ(14287)= 3.57 GΩ | Rout = Ro2 200 = = 14.0 mΩ 1+ Aβ2 14287 12.52 Use the expressions in Table 12.1. The three individual amplifier stages are the same. 5.01x10 4 92 2kΩ 1 R ⎛ Aβ ⎞ 40kΩ 21 β= = | A = 10 20 = 5.01x10 4 | Av = − 2 ⎜ = −20.0 ⎟=− R1 ⎝ 1+ Aβ ⎠ 2kΩ + 40kΩ 21 2kΩ 5.01x10 4 1+ 21 ⎛ ⎞ R2 40kΩ Ro 300Ω = 2.00 kΩ | Rout = = = 126 mΩ Rin = R1 + ⎜ Rid ⎟ = 2kΩ + 500kΩ 4 1+ A ⎠ 1+ Aβ 1+ 5.01x10 5.01x10 4 ⎝ 1+ 21 ⎞⎛ ⎞ ⎛ 2kΩ 2kΩ For the overall amplifier : Av = ⎜−20.0 ⎟⎜−20.0 ⎟(−20.0) = −8000 2kΩ + 126mΩ ⎠ 2kΩ + 126mΩ ⎠⎝ ⎝ Rin = 2.00 kΩ | Rout = 126 mΩ 12.53 50 2 < 5000 < 50 3 | Three stages will be required to keep the gain of each stage ≤ 50. However, the input and output resistance requirements may further constrain the 85 20 gains and must be checked as well. A =10 = 1.778 x 10 4 Ro 100Ω 1 For Rout = : ≤ 0.1Ω → Aβ ≥ 999 → β ≥ 0.0562 → ≤ 17.8. 1+ Aβ 1 + Aβ β 1 For Rin = Rid (1+ Aβ ) 2Ric : 1MΩ(1+ Aβ ) 2GΩ ≥ 10MΩ → Aβ ≥ 9 → ≤ 1976 β 17.8(50)(50) > 5000 so three stages is still sufficient. 12-19 12.54 VS = VO Z1 = VO Z1 + Z2 R1 R1 + R2 SC = VO (SCR + 1)R (SCR + 1)R + R 2 1 2 1 2 1 SC V ⎛ R ⎞ SC R1 R2 + 1 Av (s)= O = ⎜1+ 2 ⎟ VS ⎝ R1 ⎠ SCR2 + 1 R2 + ( ) 12.55 Av (s) = − Avnom = − f Hnom = f Hmin = 1 R2 R 1 | Av (0)= − 2 | f H = R1 sCR2 + 1 R1 2πCR2 330kΩ(1.1) 330kΩ(0.9) 330kΩ = −33 | Avmax = − = −40.3 | Avmax = − = −27.0 10kΩ 10kΩ(0.9) 10kΩ(1.1) 1 ( )3.3x10 2π 10 −10 5 = 4.83kHz | f Hmax = 1 ( )(1.2)3.3x10 (1.1) 2π 10 −10 5 1 ( )(0.5)3.3x10 (0.9) 2π 10 −10 5 = 10.7kHz = 3.65kHz 12.56 −60db/decade requires 3 poles - 3 x (-20db/decade). Using three identical fH3 = 1.96(20kHz) = 39.2kHz. amplifiers : Av = 3 1000 = 10 and f H1 = 1 R2 = 10R1 | f H = 1 | R2C = = 4.06x10−6 s 3 2πR2C 2π 39.2x10 Try C = 270 pF. R2 = 12-20 2 3 −1 1 ( ) 1 = 15.0 kΩ, R1 = 1.5kΩ 2πf H C 12.57 s + ωB Ro Ro = = Ro ω 1+ A(s)β 1+ s + ω B + ωT β T β s + ωB s s 1+ 1+ s + ωB Ro Ro ωB ωB = Ro = ≅ s s + ω B (1+ Aoβ ) (1+ Aoβ ) 1+ (1+ Aoβ ) 1+ s ω B (1+ Aoβ ) βωT A(s) = Z out ωT s + ωB | ωT = Aoω B | Z out = R OUT RO Inductive region RO 1+A o β ω ωB βω T 12.58 Using MATLAB: b=1/11; ro=100; wt=2*pi*1e6; wb=wt/1e5; n=ro*[1 wb]; d=[1 b*wt];w=logspace(0,7); r=freqs(n,d,w); mag=abs(r); phase=angle(r)*180/pi; subplot(212);semilogx(w,phase) subplot(211);loglog(w,mag) 10 2 1 Magnitud e 10 10 0 10 -1 10 -2 10 0 10 1 10 2 10 3 10 4 10 5 10 6 10 7 100 80 Phase 60 40 20 0 10 0 10 1 10 2 10 3 10 4 Frequency (rad/s) 10 5 10 6 10 7 12.59 12-21 ⎛ ⎜ ⎛ R2 ⎞ R2 ⎟⎟ = R1 + ⎜ Rid Z in = R1 + ⎜⎜ Rid ωT 1+ A(s)⎠ ⎜ ⎝ 1+ ⎜ s + ωB ⎝ Rid R2 ⎞ ⎟ ⎛ s + ωB ) ⎞ ⎟ = R1 + ⎜ Rid R2 ( ⎟ s + ω B + ωT ⎠ ⎟ ⎝ ⎟ ⎠ (s + ω B ) Rid R2 (s + ω B ) s + ω B + ωT = R1 + (s + ω B ) Rid (s + ω B + ωT ) + R2 (s + ω B ) Rid + R2 s + ω B + ωT ⎛ ⎛ s ⎞ s ⎞ R2 Rid R2ω B ⎜1+ Rid ⎜1+ ⎟ ⎟ 1+ Ao ) ( ⎝ ωB ⎠ ⎝ ωB ⎠ Z in = R1 + = R1 + R2 s Rid + R2 Rid ω B (1+ Ao ) + R2ω B + s(Rid + R2 ) Rid + 1+ (1+ Ao ) ω B (1+ Ao ) Rid + R2 (1+ Ao ) Z in = R1 + ⎛ s ⎞ 1+ ⎜ ⎟ ⎛ R2 ⎞ ⎝ ωB ⎠ ⎟ Z in = R1 + ⎜⎜ Rid Rid + R2 s (1+ Ao )⎟⎠ 1+ ⎝ ω B (1+ Ao ) R + R2 id (1+ Ao ) 12-22 12.60 Using MATLAB: n1=1e6; d1=[1 2000]; n2=1e6; d2=[1 4000]; n3=1e12; d3=[1 6000 8e6]; w=logspace(2,5); [m1,p1,w]=bode(n1,d1,w); [m2,p2,w]=bode(n2,d2,w); [m3,p3,w]=bode(n3,d3,w); subplot(211) loglog(w,m1,w,m2,w,m3) subplot(212) semilogx(w,p1,w,p2,w,p3) . 10 6 Magnitude 10 5 AV 10 4 10 3 AV1 10 2 AV2 10 1 10 0 10 2 10 4 10 3 10 5 Frequency (rad/s) 0 AV2 Phase -50 A V1 -100 AV -150 -200 10 2 10 3 Frequency (rad/s) 10 4 10 5 12-23 12.61 Av = − Z 2 Aβ Z1 1 + Aβ Av (s) = − Av (s) = − | β= Z1 Z1 + Z 2 | A= ωT R2 | Z1 = R1 | Z 2 = s +ωo sCR2 + 1 R2 ωT R1 ⎛ R ⎞ ⎛ R ⎞ s2 R2C + s⎜1 + 2 + R2C (ω o + ωT )⎟ + ω o ⎜1 + 2 ⎟ + ωT ⎝ R1 ⎠ ⎝ R1 ⎠ 3.653 x1013 s2 + 3.142 x10 7 s + 1.916 x1012 Using MATLAB: bode(-3.653e13,[1 3.142e7 1.916e12]) 30 20 10 Gain dB 0 -10 -20 -30 -40 -50 10 3 10 4 5 10 6 10 Frequency (rad/sec) 10 7 10 8 200 150 Phase deg 100 50 0 -50 -100 -150 -200 3 10 10 4 10 5 10 Frequency (rad/sec) 12-24 6 10 7 10 8 12.62 V (s) V (s) 1 which is the transfer function of an integrator (a) S = −sCVO (s) | Av (s) = O = − R VS (s) sRC (b) Generalizing Eq. (11.122) : Av (s) = − Z 2 A(s)β 1 Z1 | Z2 = | Z1 = R1 | β = Z1 1+ A(s)β Z1 + Z 2 sC ωT sRC ωT sRC R1 sCR 1 s + ω B sRC + 1 β= = | A(s)β = | Av (s) = − sRC 1 s + ω B sRC + 1 sCR + 1 sRC 1+ ωT R1 + s + ω B sRC + 1 sC sRCωT ωT 1 Av (s) = − =− sRC (s + ω B )(sRC + 1) + sRCωT (s + ω B )(sRC + 1) + sRCωT ωT ωT ωT Av (s) = − RC RC RC ≅− =− ⎛ ⎛ ⎞ ⎛ 1 ⎞ ωB ω 1 ⎞ B s + s⎜ω B + ωT + ⎟+ s + ωT )⎜ s + s + ωT )⎜ s + ( ( ⎟ ⎟ ⎝ RC ⎠ RC Ao RC ⎠ ⎝ ωT RC ⎠ ⎝ 2 using dominant root factorization where it is assumed ωT >> ω B and ωT >> |A (ω)| 1 . RC v A o Integrator region 1 A RC o ω T ω 12-25 12.63 wrc=1/(1e4*470e-12); wt=2*pi*5e6; wb=2*pi*50; n=wt*wrc; d=[1 wt+wb+wrc wb*wrc]; bode(n,d) 100 Gain dB 50 0 -50 -100 10 -1 10 0 10 1 10 2 10 3 10 4 10 Frequency (rad/sec) 5 10 6 10 7 10 8 10 0 10 1 10 2 10 3 10 4 10 Frequency (rad/sec) 5 10 6 10 7 10 8 0 Phase deg -50 -100 -150 -200 10 -1 12.64 2kΩ 1 105 = | Aβ = = 4760 >> 1 2kΩ + 40kΩ 21 21 40 kΩ 3x106 Hz R = −20 | f H = βf T = = 143kHz ( a ) Av = − 2 = − R1 2 kΩ 21 β= ( b ) Av = (−20) = −8000 (78dB) | f H 3 = 0.51 f H = 72.9 kHz 3 12-26 12.65 The table below follows the approach used in Table 12.6. The only change is the required gain 85 is Av = 10 20 = 1.778 x 10 4 . Cascade of Identical Non-Inverting Amplifiers # of Stages AV(0) Gain per Stage 1/β fH Single Stage β x fT fH N Stages RIN ROUT 1 2 3 4 5 6 7 8 9 10 11 12 2.00E+04 1.41E+02 2.71E+01 1.19E+01 7.25E+00 5.21E+00 4.12E+00 3.45E+00 3.01E+00 2.69E+00 2.46E+00 2.28E+00 5.00E+01 7.07E+03 3.68E+04 8.41E+04 1.38E+05 1.92E+05 2.43E+05 2.90E+05 3.33E+05 3.71E+05 4.06E+05 4.38E+05 5.000E+01 4.551E+03 1.878E+04 3.658E+04 5.320E+04 6.717E+04 7.839E+04 8.724E+04 9.415E+04 9.951E+04 1.037E+05 1.068E+05 6.00E+09 7.08E+11 3.69E+12 8.41E+12 1.38E+13 1.92E+13 2.43E+13 2.90E+13 3.33E+13 3.71E+13 4.06E+13 4.38E+13 8.33E+00 7.06E-02 1.36E-02 5.95E-03 3.62E-03 2.60E-03 2.06E-03 1.72E-03 1.50E-03 1.35E-03 1.23E-03 1.14E-03 We see from the spreadsheet that a cascade of seven identical stages is required to achieve the bandwidth specification. Fortuitously, it also meets the input and output resistance specs. For the non-inverting amplifier cascade: R R AV = 1+ 2 = 4.12 → 2 = 3.12 R1 R1 A similar spreadsheet for the cascade of identical inverting amplifiers indicates that it is impossible to meet the bandwidth requirement. 12-27 12.66 R2 R = 4.12 → 2 = 3.12 | Exploring the 5% resistor R1 R1 R tables, we find R2 = 62kΩ and R1 = 20kΩ yields 2 = 3.10 as a reasonable pair. R1 (a) From Problem 11.99, Av = 1 + The nominal gain of the cascade is then Av = (4.10) =1.948 x 10 4 . 7 Av = 86db ± 1dB ⇒ 1.778 x 10 4 ≤ AV ≤ 2.239 x 10 4 and the gain is well within this range. Many amplifiers will probably fail due to tolerances with 5% resistors. A Monte Carlo analysis would tell us. If we resort to 1% resistors to limit the tolerance spread, R2 = 30.9 kΩ and R1 = 10.0 kΩ is one of many possible pairs. 1 5 x10 6 | f H1 = βf T = = 1.22 MHz (b) For R2 = 62kΩ and R1 = 20kΩ, β = 4.1 4.1 1 f H = 1.22 MHz 2 7 − 1 = 394 kHz 12-28 12.67/12.68 One possibility: Use a cascade of two non-inverting amplifiers, and shunt the input of the first amplifier to define the input resistance. 60db → Av = 1000 | A single - stage amplifier with a gain of 1000 would have a bandwidth of only 5 kHz using this op - amp. Two stages should be sufficient if Rin and R out can also be met. A design with f H 2 >> f H1 will be tried. First stage : Non - inverting with bandwidth of 20 kHz f 20kHz 1 β1 = H1 = = 0.004 | Av1 = = 250 → Av 2 = 4 → β 2 = 0.25 → f H 2 = 1.25 MHz fT 5 MHz β1 Since f H 2 >> f H1, f H = f H1 = 20kHz. Ao = 85 dB = 17800 100 Ro2 = = 0.0225Ω which is ok. Checking Rout = 1 + Aoβ 2 1 + 17800(0.25) Choosing resistors from the Appendix, a possible set is Amplifier 1: R1 = 1.2kΩ, R 2 = 300 kΩ and shunt the input with R 3 = 27kΩ Amplifier 2 : R1 = 3.3kΩ, R 2 = 10 kΩ ⎞ ⎛ ⎜ 17800 17800 ⎟ = 997.5 = 60.0 dB Checking gain : Av = ⎜ 17800 17800 ⎟ ⎟ ⎜1 + 1+ 251 ⎝ 4.03 ⎠ vS + + vO 27 k Ω 300 k Ω 10 k Ω 1.2 k Ω 3.3 k Ω 12-29 12.69 function sg=Prob103(tol); sg=0; for j=1:10 ao=100000; ft=1e6*sqrt(2^(1/6)-1); for i=1:500, r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g1=ao/(1+ao*beta); b1=beta*ft; r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g2=ao/(1+ao*beta); b2=beta*ft; r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g3=ao/(1+ao*beta); b3=beta*ft; r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g4=ao/(1+ao*beta); b4=beta*ft; r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g5=ao/(1+ao*beta); b5=beta*ft; r1=22000*(1+2*tol*(rand-0.5));r2=130000*(1+2*tol*(rand-0.5)); beta=r1/(r1+r2);g6=ao/(1+ao*beta); b6=beta*ft; gain(i)=g1*g2*g3*g4*g5*g6; bw(i)=(b1+b2+b3+b4+b5+b6)/6; end; sg=sg+sum(gain<1e5 | bw<5e4); end; end (a) For 5000 test cases with tol = 0.05, 33.5% of the amplifiers failed to meet either the gain or bandwith requirement. (b) For 10000 test cases with tol = 0.015, 0.1% of the amplifiers failed to meet either the gain or bandwith requirement. 12-30 12.70 1 1 Z 1 ⎛ 1 ⎞N 1 1 fH 2 N − 1 (2 − 1)2 fT N a = G → β = | f = β f | f = 2 − 1 | = = for Z = ( )⎜ ⎟ H1 T H 1 1 1 Z fT G N ⎝β ⎠ GN GN GN 1 1 ⎡1 ⎤ − G Z ⎢ (2 Z − 1) 2 2 Z ln2⎥ − (2 Z − 1)2 G Z ln G d ⎛ fH ⎞ ⎣2 ⎦ For 2 Z = e Z ln 2 and G Z = e Z ln G : ⎜ ⎟= 2Z dz ⎝ f T ⎠ G 1 1 ⎡ ⎤ − d ⎛ fH ⎞ Z 1 Z Z Z Z Z Z Setting ⎜ ⎟ = 0 → G ⎢ (2 − 1) 2 2 ln2⎥ − (2 − 1)2 G ln G = 0 → 2 ln2 = 2(2 − 1)ln G 2 dz ⎝ f T ⎠ ⎣ ⎦ ⎛ 2ln G 2ln G ⎞ 2Z = − → Z ln2 = ln⎜ − ⎟ ⎝ ln2 − 2ln G ⎠ ln2 − 2ln G ⎛ ⎞ ln G ln⎜− ⎟ ln2 ⎝ ln G − ln 2 ⎠ → N opt = Z= ⎛ ⎞ ln G ln2 ln⎜ ⎟ ⎝ ln G − ln 2 ⎠ ln2 = 22.7 which agrees with the spreadsheet in Table 12.8 (b) N opt = ⎛ ⎞ ln10 5 ln⎜ ⎟ 5 ⎝ ln10 − ln 2 ⎠ f Hopt = 106.0 kHz 12.71 22kΩ 1 5x10 4 = Aβ = = 7240 >> 1 22kΩ + 130kΩ 6.91 6.91 R 130kΩ (a) Avnom = 1+ 2 = 1+ = 6.91 22kΩ R1 β nom = Avmax = 1+ 130kΩ(1.05) 130kΩ(0.95) R2 R = 1+ = 7.53 | Avmin = 1+ 2 = 1+ = 6.35 R1 R1 22kΩ(0.95) 22kΩ(1.05) f Hnom = β nom f T = 106 Hz 106 Hz 106 Hz = 145 kHz | f Hmax = = 157 kHz | f Hmin = = 133 kHz 6.91 6.36 7.53 12-31 12.72 function [gain,bw]=Prob1272a ao=50000; ft=1e6; for i=1:500, r1=22000*(1+0.1*(rand-0.5)); r2=130000*(1+0.1*(rand-0.5)); beta=r1/(r1+r2); gain(i)=ao/(1+ao*beta); bw(i)=beta*ft; end; end [gain,bw]=prob1272a; mean(gain) ans = 6.9140 std(gain) ans = 0.2339 mean(bw) ans = 1.4478e+05 std(bw) ans = 4.8969e+03 Three sigma limits: 6.21 ≤ Av ≤ 7.62 130 kHz ≤ BW ≤ 159 kHz function [gain,bw]=Prob1272b for i=1:500, ao=100000*(1+1.0*(rand-0.5)); ft=2e6*(1+1.0*(rand-0.5)); r1=22000*(1+0.1*(rand-0.5)); r2=130000*(1+0.1*(rand-0.5)); beta=r1/(r1+r2); gain(i)=ao/(1+ao*beta); bw(i)=beta*ft; end; end [gain,bw]=prob1272b; mean(gain) ans = 6.9201 std(gain) ans = 0.2414 mean(bw) ans = 2.8925e+05 std(bw) ans = 8.5536e+04 Note that the bandwidth is essentially a uniform distribution. 3σ: 6.20 ≤ Av ≤ 7.64 98.9% of the values fall between: 146 kHz ≤ BW ≤ 439 kHz 12.73 ( ) SR ≥ VOω = (15V )(2π ) 2x10 4 Hz = 1.89x106 12.74 f = SR 10V 1 = −6 = 159 kHz 2πVo 10 s 20πV 12.75 12-32 V V or 1.89 s µs The negative transition requires the largest slew rate : SR = V ∆V 20V = = 10 2µs ∆t µs 12.76 (a) For the circuit in Fig. 12.26 : Rid = 250 kΩ | R = 1 kΩ − an arbitrary choice ωB = ( 2π 5 x106 8 x10 4 ) = 125π rad/s | C= 1 ωB R = 1 (125π )1000 = 2.55 µF | Ro = 50Ω | Ao = 80,000 (b) Add a resistor from each input terminal to ground of value 2 R IC = 1 GΩ. See Prob. 11.111 for schematics. 12.77 Two possibilities: 105 nA 1 mV + v 1 250 k Ω 50 Ω 1k Ω 200 MΩ - + + + v v 1 80,000v 2 2 v o 2.55 µF 200 M Ω 95 nA 1 mV - + + 50 Ω 1k Ω 105 nA 125 k Ω v 1 + + 100 M Ω v 1 v 80,000v 2 2 vo 2.55 µF 125 k Ω 95 nA 12-33 12.78 100 Ω + v v1 400 k Ω ω1 : C = 1 1 Ω + v 1.592 v2 2 µF 1.592 80,000v µF 1 1 = = 1.592 µF − setting R1 arbitrarily to 100 Ω. ω1R1 2π (10 3 )(100) ω 2 : R2 = 1 1 = = 1 Ω − Using the same value of C. 5 ω 2C 2π (10 )(1.592 µF ) 12.79 *PROBLEM 12.79 - Six-Stage Amplifier VS 1 0 AC 1 XA1 1 2 0 AMP XA2 2 3 0 AMP XA3 3 4 0 AMP XA4 4 5 0 AMP XA5 5 6 0 AMP XA6 6 7 0 AMP .SUBCKT AMP 1 2 7 RID 1 3 1E9 RO 6 2 50 E2 6 7 5 7 1E5 E1 4 7 1 3 1 R 4 5 1K C 5 7 15.915UF R2 2 3 130K R1 3 7 22K .ENDS .TF V(7) VS .AC DEC 40 1 1MEG .PRINT AC V(1) V(2) V(3) V(4) V(5) V(6) V(7) .PROBE V(1) V(2) V(3) V(4) V(5) V(6) V(7) .END 12-34 75 Ω + v3 + 3 vo 12.80 Student PSPICE cannot handle 6 copies of the uA741 op amp, but since all the stages are the same, we can square the output from a 3-stage version or cube the output from a two-stage model. 200 100 0 -100 100Hz 300Hz 1.0KHz DB(V(I1:+))+ DB(V(I1:+)) 3.0KHz 10KHz 30KHz 100KHz 300KHz 1.0MHz 3.0MHz 10MHz Frequency From the SPICE graph, BW = 54.3 kHz. 12-35 12.81 *PROBLEM 12.81 - Six Stage Amplifier VS 1 0 AC 1 XA1 1 2 0 AMP XA2 2 3 0 AMP XA3 3 4 0 AMP XA4 4 5 0 AMP XA5 5 6 0 AMP XA6 6 7 0 AMP .SUBCKT AMP 1 2 8 RID 1 3 1E9 RO 7 2 50 E2 7 8 6 8 1E5 *Two dummy loops provide separate control of Gain & BW tolerances G1 8 4 1 3 .001 R11 4 8 RG 1000 E1 5 8 4 8 1 RC 5 6 1000 C 6 8 CC 15.915UF * R2 2 3 RR 130K R1 3 8 RR 22K .ENDS .MODEL RR RES (R=1 DEV=5%) .MODEL RG RES (R=1 DEV=50%) .MODEL CC CAP (C=1 DEV=50%) .AC DEC 20 1E3 1E6 .PROBE V(7) .PRINT AC V(7) .MC 1000 AC V(7) MAX OUTPUT(EVERY 20) *.MC 1000 AC V(7) MAX OUTPUT(RUNS 77 573 597 777) .END Maximum gain = 103 dB; Minimum gain = 98.5 dB Maximum Bandwidth = 65 kHz; Minimum bandwidth = 38 kHz (These are approximate.) 12.82 1 = 7.96 pF 2π (1000Ω)(20 MHz) Rid = 1010 Ω C= 12.83 A ≥ 118 dB CMRR ≥ 80 dB I B ≤ 8.8 nA IOS ≤ 2.2 nA 12-36 Ro not specified PSRR ≥ 100 dB VOS ≤ 1.5 mV Power Supplies ± 18 V maximum Nominal values only : Rid = 1010 Ω 12.84 A = 4 x106 SR = 12.5 V/µs nominal f T = 20 MHz (a ) Use the expressions in Tables 12.1 and 12.2. 100 47 kΩ 1 15kΩ 1 18 kΩ 1 = | βB = = | βC = = 47kΩ + 470kΩ 11 15kΩ + 150kΩ 11 18 kΩ + 270 kΩ 16 5 10 105 R ⎛ Aβ ⎞ R ⎛ Aβ ⎞ 470kΩ 11 150 kΩ 11 AvA = − 2 ⎜ = −10.0 AvB = − 2 ⎜ = −10.0 ⎟=− ⎟=− 5 R1 ⎝ 1 + Aβ ⎠ 47kΩ R1 ⎝1 + Aβ ⎠ 15kΩ 10 105 1+ 1+ 11 11 5 10 R2 ⎛ Aβ ⎞ 270 kΩ 16 AvC = − ⎜ = −15.0 Av = −10.02 (−15)= −1500 ⎟=− 5 R1 ⎝ 1 + Aβ ⎠ 18kΩ 10 1+ 16 ⎛ ⎞ R2 470 kΩ Rin = RinA = R1 + ⎜ Rid = 47.0 kΩ ⎟ = 47 kΩ + 1MΩ 1 + A⎠ 1 + 105 ⎝ A = 10 20 = 105 | β A = Ro 250Ω = = 40.0 mΩ 1 + Aβ 105 1+ 16 2 MHz 2 MHz f HA = f HB = β A fT = = 182kHz f HC = βC fT = = 125kHz 11 16 For the overall amplifier : Av = −1500 | Rin = 47.0 kΩ | Rout = 40.0 mΩ Rout = RoutC = Using the definition of bandwidth : 10 10 ⎛ f H ⎞2 1+ ⎜ ⎟ ⎝182 kHz ⎠ (b) v S ⎛ f H ⎞2 1+ ⎜ ⎟ ⎝182 kHz ⎠ 15 ⎛ f H ⎞2 1+ ⎜ ⎟ ⎝ 125kHz ⎠ = 1500 2 → f H = 79.9 kHz = 50.0 mV | vOA = −10vS = −500 mV | vOB = −10vOA = +5.00 V | vOA v = +5.00 µV | v -B = OB5 = −50.0 µV 5 -10 -10 The output of the third amplifier is saturated at -18 V, and the inverting input is no longer near 270kΩ 18 kΩ ground potential. Using superposition, v -C = 5V + (−18V ) = +3.56 V 18kΩ + 270kΩ 18kΩ + 270kΩ The remaining three nodes are V+ = +18 V V− = −18 V and Vgnd = 0 V . vO = −15vOB = −75.0V > 18V → vO = −18 V | v -A = 12-37 12.85 100 47kΩ 1 15kΩ 1 = | βB = = 47kΩ + 470kΩ 11 15kΩ + 150kΩ 11 ⎛ 470kΩ ⎞⎛ 150kΩ ⎞⎛ 270kΩ ⎞ 18kΩ 1 βC = = Aβ >> 1 Avnom ≅ ⎜− ⎟⎜ − ⎟⎜− ⎟ = −1500 18kΩ + 270kΩ 16 ⎝ 47kΩ ⎠⎝ 15kΩ ⎠⎝ 18kΩ ⎠ A = 10 20 = 105 | β A = max v A ⎛ 1.05 ⎞3 ≅ −1500⎜ ⎟ = −2025 ⎝ 0.95 ⎠ min v A ⎛ 0.95 ⎞3 ≅ −1500⎜ ⎟ = −1111 ⎝ 1.05 ⎠ max Rinmax ≅ RinA = 47.0 kΩ(1.05)= 49.4 kΩ nom Rinnom ≅ RinA = 47.0 kΩ min Rinmin ≅ RinA = 47.0 kΩ(0.95)= 44.7 kΩ Ro 250Ω = = 40.0 mΩ 1+ Aβ 105 1+ 16 R 250Ω Ro 250Ω max max min min o ≅ RoutC = = = 43.9 mΩ Rout ≅ RoutC = = = 36.4 mΩ Rout min 5 max 1+ Aβ 1+ Aβ 10 105 1+ 1+ 17.6 14.6 2 MHz 2 MHz = 182kHz f HC = βC fT = = 125kHz f HA = f HB = β A fT = 11 16 Using the definition of bandwidth : nom nom ≅ RoutC = Rout 10 10 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝182kHz ⎠ 15 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝182kHz ⎠ 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝ 125kHz ⎠ = 1500 2 → f H = 79.8 kHz 2 MHz 2 MHz = 200kHz f HC = βC fT = = 137kHz 10.0 14.6 9.048 13.57 1111 = → f Hmax = 87.5 kHz 2 2 2 ⎛ f max ⎞ ⎛ f max ⎞ 1+ ⎜ H ⎟ 1+ ⎜ H ⎟ ⎝ 200kHz ⎠ ⎝ 137kHz ⎠ max max f HA = f HB = β A fT = 9.048 ⎛ f max ⎞2 1+ ⎜ H ⎟ ⎝ 200kHz ⎠ 2 MHz 2 MHz = 167kHz f HC = βC fT = = 114kHz 12.0 17.6 11.05 16.58 2025 = → f Hmax = 73.0 kHz 2 2 2 ⎛ f max ⎞ ⎛ f max ⎞ H H 1+ ⎜ ⎟ 1+ ⎜ ⎟ ⎝167kHz ⎠ ⎝ 114kHz ⎠ max max f HA = f HB = β A fT = 11.05 2 ⎛ f max ⎞ 1+ ⎜ H ⎟ ⎝167kHz ⎠ 12-38 12.86 (a ) Use the expressions in Tables 12.1 and 12.2. Three identical gain blocks. A = 10 106 20 = 2.00x105 | β = 3kΩ 1 A = | Aβ = 14286 | Av1 = = 14.0 3kΩ + 39kΩ 14 1+ Aβ Av = 14.03 = 2744 Rin = RinA = 1MΩ Rid (1+ Aβ )= 1MΩ 500kΩ(1+ 14286)= 1.00 MΩ Rout = RoutC = Ro 300Ω = = 21.0 mΩ 1+ Aβ 1+ 14286 1 5MHz = 357kHz f H = f H1 2 3 −1 = 182kHz f H1 = β A f T = 14 For the overall amplifier : Av = +2740 | Rin = 1.00 MΩ | Rout = 21.0 mΩ | f H = 182kHz (b) v I = 5.00 mV | vOA = 14vI = 70.0 mV | vOB = 14vOA = 980 mV | vOA v = +5.00 mV | v-B = OB = 70.0 mV 14 14 The output of the third amplifier is saturated at 12 V, and the inverting and non - inverting inputs vO = 14vOB = 13.7V > 12V → vO = 12.0 V | v- A = are no longer equal. v-C = 12V 3kΩ = 0.857 V. V+ = +12 V 3kΩ + 39kΩ V− = −12 V Vgnd = 0 V 12.87 (a ) Use the expressions in Tables 12.1 and 12.2. Three identical gain blocks. A = 10 106 20 = 2.00x105 | β = 1.5kΩ 1 A = | Aβ = 7407 | Av1 = = 27.0 1.5kΩ + 39kΩ 27 1+ Aβ Av = 27.03 = 19700 Rin = RinA = 1.5MΩ Rid (1+ Aβ ) = 1.5MΩ 500kΩ(1+ 14286) = 1.50 MΩ Rout = RoutC = Ro 300Ω = = 38.8 mΩ 1+ Aβ 1+ 7407 1 5MHz = 185kHz f H = f H1 2 3 −1 = 94.3kHz f H1 = β A f T = 27 For the overall amplifier : Av = +19700 | Rin = 1.50 MΩ | Rout = 38.8 mΩ | f H = 94.3 kHz (b) v I = 5.00 mV | vOA = 27vI = 135 mV | vOB = 27vOA = 3.65 V | vOA v = +5.00 mV | v-B = OB = 135 mV 27 27 The output of the third amplifier is saturated at 12 V, and the inverting and non - inverting inputs vO = 27vOB = 98.4V > 12V → vO = 12.0 V | v- A = are no longer equal. v-C = 12V 1.5kΩ = 0.444 V. V+ = +12 V 1.5kΩ + 39kΩ V− = −12 V Vgnd = 0 V 12-39 12.88 Three identical stages : β nom = 3kΩ 1 = 3kΩ + 39 kΩ 14 Aβ = 2 x105 = 14286 >> 1 14 A ⎛ R2 ⎞3 ⎛ 39 kΩ ⎞3 = ⎜1 + ⎟ = ⎜1 + ⎟ = 2740 3kΩ ⎠ ⎝ R1 ⎠ ⎝ Avmax ⎡ 39 kΩ(1.02)⎤ ⎡ 39 kΩ(0.98)⎤ ⎥ = 3070 | Avmin = ⎢1 + ⎥ = 2460 = ⎢1 + 3kΩ(1.02) ⎥⎦ ⎢⎣ 3kΩ(0.98) ⎥⎦ ⎣⎢ nom v 3 3 Rinnom = 1 MΩ | Rinmax = 1 MΩ(1.02) = 1.02 MΩ | Rinmin = 1 MΩ(0.98) = 980 kΩ 300 300 min = 21.8 MΩ | Rout = = 20.2 MΩ 5 2 x10 2 x105 1+ 1+ 14.53 13.49 5 MHz 5 MHz 5 MHz f Hnom = β nom f T = = 357 kHz | f Hmax = = 371 kHz | f Hmin = = 344 kHz 14 13.49 14.53 nom = Rout 300 max = 21.0 MΩ | Rout = 1 + 14286 12-40 12.89 (a ) Use the expressions in Tables 12.1 and 12.2. 80 10kΩ 1 2kΩ 1 10kΩ 1 = | βB = = | βC = = 10kΩ + 39kΩ 4.9 2kΩ + 200kΩ 101 10kΩ + 39kΩ 4.9 4 10 A 10000 R2 ⎛ Aβ ⎞ 200kΩ 101 AvC = AvA = = = +4.90 AvB = − ⎜ = −99.0 ⎟=− 10000 R1 ⎝ 1+ Aβ ⎠ 1+ Aβ 2kΩ 10 4 1+ 1+ 4.9 101 ⎛ ⎞ 10000 Av = 4.902 (−99.0)= −2380 Rin = RinA = Rid (1+ Aβ )= 300kΩ⎜1+ ⎟ = 613 MΩ 4.9 ⎠ ⎝ A = 10 20 = 10 4 | β A = Ro 250Ω = = 98.0 mΩ 1+ Aβ 10 4 1+ 4.9 3MHz 3MHz f HC = f HA = β A fT = = 612kHz f HC = βC fT = = 29.7kHz 4.9 101 For the overall amplifier : Av = −2380 | Rin = 613 MΩ | Rout = 98.0 mΩ Rout = RoutC = Using the definition of bandwidth : 4.9 99 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝ 612kHz ⎠ 4.9 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝ 29.7kHz ⎠ 2 ⎛ fH ⎞ 1+ ⎜ ⎟ ⎝ 612kHz ⎠ = 2380 2 → f H = 29.6 kHz Note that the bandwidth is controlled by amplifier B because it's bandwidth is much smaller than the others. (b) v I = 00.0 mV | vOA = 4.9vOS = +49.0 mV | vOB = −100vOA + 101(10mV ) = −3.89V | vO = 4.9(vOB + .010) = −19.0V < -15V → vO = −15 V | v -A = v -C = − vOA v = 10.0 mV | v -B = OB4 = +389 µV 4.9 -10 15V = −3.06 V The remaining three nodes are V+ = +15 V 4.9 V− = −15 V and Vgnd = 0 V. 12-41 12.90 10kΩ 1 2kΩ 1 A = 10 = 10 4 | βC = β A = = | βB = = 10kΩ + 39kΩ 4.9 2kΩ + 200kΩ 101 2 ⎛ 39kΩ ⎞ ⎛ 200kΩ ⎞ Aβ >> 1 Avnom ≅ ⎜1+ ⎟ ⎜− ⎟ = −2401 ⎝ 10kΩ ⎠ ⎝ 2kΩ ⎠ 80 20 2 max v A ⎛ 39kΩ ⎛ 1.10 ⎞⎞ ⎛ 200kΩ ⎛ 1.10 ⎞⎞ ≅ ⎜1+ ⎟⎟ ⎜ − ⎟⎟ = −4064 ⎜ ⎜ ⎝ 10kΩ ⎝ 0.90 ⎠⎠ ⎝ 2kΩ ⎝ 0.90 ⎠⎠ ⎛ 39kΩ ⎛ 0.90 ⎞⎞2⎛ 200kΩ ⎛ 0.90 ⎞⎞ A ≅ ⎜1+ ⎟⎟ ⎜ − ⎟⎟ = −1437 ⎜ ⎜ ⎝ 10kΩ ⎝ 1.10 ⎠⎠ ⎝ 2kΩ ⎝ 1.10 ⎠⎠ ⎡ ⎛ 1 ⎞⎤ Rinnom = Rid (1+ Aβ ) = 300kΩ ⎢1+ 10 4 ⎜ ⎟⎥ = 612 MΩ ⎝ 4.9 ⎠⎦ ⎣ ⎡ ⎡ ⎛ 1 ⎞⎤ ⎛ 1 ⎞⎤ 4 min Rinmax = 300kΩ ⎢1+ 10 4 ⎜ ⎟⎥ = 716 MΩ Rin = 300kΩ ⎢1+ 10 ⎜ ⎟⎥ = 521 MΩ ⎝ 4.19 ⎠⎦ ⎝ 5.77 ⎠⎦ ⎣ ⎣ min v Ro 200Ω = = 98.0 mΩ 1+ Aβ 10 4 1+ 4.9 Ro 200Ω Ro 200Ω max max min min Rout ≅ RoutC = = = 115 mΩ Rout ≅ RoutC = = = 83.4 mΩ min 4 max 1+ Aβ 1+ Aβ 10 10 4 1+ 1+ 5.77 4.19 3MHz 3MHz f HA = f HB = β A fT = = 612 kHz f HC = β B fT = = 29.7kHz 4.9 101 The bandwidth is controlled by the narrow bandwidth stage. nom nom ≅ RoutC = Rout f Hnom = 29.7 kHz 12-42 f Hmin = β Bmin f T = 3MHz = 24.3 kHz 123 f Hmax = β Bmax f T = 3MHz = 36.2 kHz 82.8 CHAPTER 13 13.1 Assuming linear operation : vBE = 0.700 + 0.005sin 2000πt V ⎡⎛ 5mV ⎞ ⎤ vce = ⎢⎜ ⎟(−1.65V )⎥ sin 2000πt = −1.03sin 2000πt V ⎣⎝ 8mV ⎠ ⎦ vCE = 5.00 −1.03sin 2000πt V ; 10 - 3300IC ≥ 0.700 → IC ≤ 2.82 mA 13.2 Assuming linear region operation : vGS = 3.50 + 0.25sin 2000πt V ⎡ 0.25V ⎤ vds = ⎢ −2V )⎥ sin 2000πt = −1.00sin 2000πt V ( ⎣0.50V ⎦ vDS = 4.80 −1.00sin 2000πt V vDS ≥ vGS − VTN →10 − 3300I D −1.00sin 2000πt ≥ 3.50 + 0.25sin 2000πt −1 For sin 2000πt = 1, I D ≤ 10 −1− 3.5 − 0.25 + 1 V = 1.89 mA Ω 3300 13.3 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the collector to the output vO. C3 is a bypass capacitor. (b) The signal voltage at the top of resistor R4 will be zero. 13.4 (a) C1 is a bypass capacitor. C2 is a coupling capacitor that couples the ac component of vI into the amplifier. C3 is a coupling capacitor that couples the ac component of the signal at the collector to output vO. (b) The signal voltage at the base will be vb = 0. 13.5 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the collector to output vO. (b) The signal voltage at the emitter will be ve = 0. 13.6 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. (b) The signal voltage at the source will be vs = 0. 13.7 13-1 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. 13.8 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. (b) The signal voltage at the source will be vs = 0. 13.9 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the collector to output vO. (b) The signal voltage at the emitter will be ve = 0. 13.10 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the signal from the emitter of Q1 back to the node joining R1 and R2. C3 is a coupling capacitor that couples the ac component of the signal at the emitter to the output vO. (b) The signal voltage at the collector will be zero. 13.11 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the drain to the output vO. (b) The signal voltage at the top of R4 will be zero. 13.12 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. 13.13 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the drain to the output vO. 13.14 dc voltage sources produce constant values of output voltage. Hence no signal voltage can appear at the terminals of the source. The signal component of the voltage is forced to be zero, and a direct path to ground is provided for signal currents. 13-2 13.15 NPN Common-Emitter Amplifier +18 V 270 k Ω REQ REQ Q1 360kΩ = 5.84 V 360kΩ + 750kΩ = R1 R2 = 360kΩ 750kΩ = 243 kΩ VEQ = 18V ( ) 5.84 = 243x103 I B + 0.7 + 91 228.2x103 I B 243 k Ω I B = 0.245 µA | IC = 90I B = 22.0 µA VEQ 5.84 V 228.2 k Ω VCE = 18 − 2.7x105 IC − 2.28x105 I E = 6.99 V Q − point : (22.0 µA, 6.99 V ) 13.16 SPICE results: (a) (22.5 µA, 6.71 V) (b) (22.6 µA, 6.69 V) The discrepancies between the results in Probs. 13.15 and 13.16 arise because VBE = 0.575 V with IS = 5 fA. Very little changes occurs with the addition of VA. 13.17 NPN Common-Emitter Amplifier +12 V 5kΩ = −4 V 5kΩ + 10kΩ = R1 R2 = 5kΩ 10kΩ = 3.33 kΩ VEQ = −12V + 24V 6k Ω REQ R EQ −4 = 3300I B + 0.7 + 76(4000)I B −12 Q1 3.33 k Ω I B = 23.8 µA | IC = 75I B = 1.78 mA VEQ -4 V 4k Ω -12 V VCE = 12 − 6000IC − 4000I E − (−12) = 6.08 V Q − point : (1.78 mA, 6.08 V ) 13-3 13.18 *Problem 13.17 - NPN Common-Emitter Amplifier VCC 7 0 DC 12 VEE 8 0 DC -12 R1 3 8 5K R2 7 3 10K RE 4 8 4K RC 7 5 6K Q1 5 3 4 NBJT .OP .MODEL NBJT NPN IS=1E-15 BF=75 VA=75 .END Results: IC 1.78E-03 VCE 6.14E+00 VBE 7.28E-01 13.19 PNP Common-Base Amplifier -7.5 V 33 k Ω 7.5 = 3000IB + 66(68000)IB + 0.7 Q1 IB = 1.51 µA | IC = 98.4 µA 3k Ω 68 k Ω +7.5 V 13-4 VEC = 15 − 33000IC − 68000IE = 4.96 V Q − point : (98.4 µA,4.96 V ) 13.20 *Problem 13.19 - PNP Common-Base Amplifier VEE 1 0 DC 7.5 VCC 5 0 DC -7.5 RC 5 4 33K RB 3 0 3K RE 1 2 68K Q1 4 3 2 PBJT .OP .MODEL PBJT PNP IS=1E-16 BF=65 VA=75 .END Results: IC -9.83E-05 VCE -4.97E+00 VBE -7.13E-01 13.21 PNP Common-Emitter Amplifier +9 V 62kΩ = 6.80V 62kΩ + 20kΩ = 62kΩ 20kΩ = 15.1kΩ VEQ = 9V REQ 3.9 k Ω 9 = 3900(136)IB + 0.7 + 15100IB + 6.80 R EQ Q1 VEQ IB = 2.75 µA | IC = 371 µA | IE = 374 µA 15.1 k Ω +6.80 V 13 k Ω VEC = 9 − 3900IE −13000IC = 2.72 V Q − point : (371 µA, 2.72 V ) 13.22 *Problem 13.21 - PNP Common-Emitter Amplifier VCC 4 0 DC 9 RC 1 0 13K R2 2 0 62K R1 4 2 20K RE 4 3 3.9K Q1 1 2 3 PBJT .OP .MODEL PBJT PNP IS=1E-15 BF=135 VA=75 .END Results: IC -3.73E-04 VCE -2.68E+00 VBE -6.88E-01 13-5 13.23 NMOS Common-Source Amplifier 1MΩ = 4.05V 1MΩ + 2.7MΩ = 1MΩ 2.7MΩ = 730kΩ VEQ = 15V +15 V REQ 82 k Ω R EQ M1 VEQ ID = 0.25mA 2 (VGS −1) 2 VGS = 4.05 − 27000ID ID = 0.125mA(3.05 − 27000IDS ) → ID = 82.2 µA 2 730 k Ω 27 k Ω VDS = 15 − 82000ID − 27000ID = 6.04V 4.05 V Q − point : (82.2 µA, 6.04 V ) 13.24 *Problem 13.23 - NMOS Common-Source Amplifier VDD 4 0 DC 15 RD 4 3 82K R2 4 2 2.7MEG R1 2 0 1MEG R4 1 0 27K M1 3 2 1 1 NFET .OP .MODEL NFET NMOS KP=250U VTO=1 .END Results: ID 8.29E-05 VDS 5.96E+00 VGS 1.81E+00 13.25 Depletion-mode NMOS Common-Gate Amplifier +15 V 4.3 k Ω M1 3.9 k Ω 5x10−4 2 (VGS + 2) | VGS = −3900ID 2 5x10−4 2 VGS = −3900 (VGS + 2) → VGS = −0.990V 2 V ID = − GS = 254 µA 3900 VDS = 15 − 4300ID − 3900ID = 12.9V ID = Q − point : (254 µA, 12.9 V ) 13-6 13.26 *Problem 13.25 - Depletion-mode NMOS Common-Gate Amplifier VDD 3 0 DC 15 RD 3 2 4.3K R1 1 0 3.9K M1 2 0 1 1 NDMOS .OP .MODEL NDMOS NMOS KP=500U VTO=-2 .END Results: ID 2.54E-04 VDS 1.29E+01 VGS -9.92E-01 13.27 PMOS Common-Source Amplifier VEQ = 18V 22 k Ω REQ R EQ M1 VEQ 1.65 M Ω 24 k Ω 9.00 V 3.3MΩ = 9.00V 3.3MΩ + 3.3MΩ = 3.3MΩ 3.3MΩ = 1.65MΩ +18 V 18 = 22000ID − VGS + 9 ⎛ 4 x10−4 ⎞ 2 9 = 22000⎜ ⎟(VGS + 1) − VGS ⎝ 2 ⎠ VGS = −2.24V | ID = 307 µA VDS = 18 − 22000ID − 24000ID = −3.88 V Q − point : (307 µA, 3.88 V ) 13.28 *Problem 13.27 - PMOS Common-Source Amplifier VDD 4 0 DC 18 RD 1 0 24K R2 4 2 3.3MEG R1 2 0 3.3MEG R4 4 3 22K M1 1 2 3 3 PFET .OP .MODEL PFET PMOS KP=400U VTO=-1 .END Results: ID -3.07E-04 VDS -3.86E+00 VGS -2.24E+00 13-7 13.29 NPN Common-Collector Amplifier +9 V 9 = 86000IB + 101(82000)IB + 0.7 Q1 IB = 0.992 µA | IC = 99.2 µA 86 k Ω 82 k Ω VCE = 18 − 82000IE = 18 − 82000(100µA) = 9.80 V -9 V Q − point : (99.2 µA,9.80 V ) 13.30 *Problem 13.29 - NPN Common-Collector Amplifier VCC 5 0 DC 9 VEE 8 0 DC -9 R1 3 6 43K R2 6 0 43K RE 4 8 82K Q1 5 3 4 NBJT .OP .MODEL NBJT NPN IS=1E-16 BF=100 VA=75 .END Results: IC 9.93E-05 VCE 9.79E+00 VBE 13.31 PMOS Common-Gate Amplifier 7.12E-01 12 + VGS 200x10−6 2 = (VGS −1) 33000 2 VGS = −0.84V | ID = 338 µA ID = VDS = −(12 − 33000ID − 22000ID + 12) M1 +12 V 33 k Ω 22 k Ω -12 V VDS = −5.41 V Q − point : (338 µA, - 5.41 V ) 13-8 13.32 *Problem 13.31 - PMOS Common-Gate Amplifier VDD 4 0 DC 12 VSS 1 0 DC -12 RD 2 1 22K R1 4 3 33K M1 2 0 3 3 PFET .OP .MODEL PFET PMOS KP=200U VTO=+1 .END Results: ID -3.38E-04 VDS -5.40E+00 VGS -8.39E-01 13.33 RS = 1 kΩ, R4 = 1 kΩ +18 V 3.9 k Ω IG = 0, so VG = 0. Assume active region operation. 2 4x10−4 VGS + 5) | VGS = −2000I D ( 2 M 2 4x10−4 VGS = −2000 VGS + 5) → VGS = −2.50V ( 2 V I D = − GS = 1.25 mA 2000 2 k Ω VDS = 18 − 3900I D − 2000I D = 10.6V ID = RG 10 M Ω Q − point : (1.25 mA, 10.6 V ) 13.34 SPICE results: The Q-point is the same (1.25 mA, 10.6 V) . 13-9 13.35 +15 V 7.5 k Ω M RG 2 225x10−6 0 − (−3) = 1.01 mA IG = 0, so VG = 0 and VGS = 0. I D = 2 VDS = 15 − 7500I D = 7.41V Q − point : (1.01 mA, 7.41 V ) [ 2.2 M Ω ] 13.36 SPICE results: The Q-point is the same (1.01 mA, 7.41 V). 13.37 (a) + Q R C R RI vi vo 3 - R1 R2 RE (b) vi + + RI RB rπ ro v - gmv RE 13-10 RC R 3 vo - (c) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the collector to the output vO. C3 is a bypass capacitor. 13.38(a) Figure P13.4 Q1 RI v + R RE i R C vo 3 - (a) (c ) ro - RI v R i g v m v E rπ + RC R3 vo + (b) C1 − Bypass C2 − Coupling - C3 − Coupling 13.38(b) Figure P13.5 RI + Q1 vi R1 R R C v 3 o R2 (c ) - (a) C1 − Coupling RI vi (b) R1 R2 rπ + + v vo - gmv ro R C R 3 - C2 − Bypass C3 − Coupling 13-11 13.39(a) Figure P13.9 + Q R RI R vi R C v 3 o R 1 (c ) - 2 (a) C1 − Coupling RI vi R R 1 (b) rπ 2 + + v v g v - m r o R C R 3 Q1 RI R 1 vi + R RE 2 (a) R v 3 o - (c ) + RI R1 vi 13-12 C2 − Bypass - C3 − Coupling 13.39(b) Figure P13.10 (b) o rπ v - C1 − Coupling ro g v m C2 − Coupling + R2 RE R v 3 - o C3 − Coupling 13.40(a) Figure P13.6 R I + M 1 R R D vi R1 v 3 o R (c ) - 2 (a) C1 − Coupling + R I vi + v R1 R 2 - (b) r gm v R o D R vo 3 C2 − Bypass - C3 − Coupling 13.40(b) Figure P13.7 M 1 + RI vi R D R1 R v 3 o - (a) (c ) ro - RI vi (b) R 1 v + + gmv RD R 3 vo C1 − Coupling - C2 − Coupling 13-13 13.41(a) Figure P13.8 + M 1 RD RI vi R1 R v 3 o R2 (c ) - (a) C1 − Coupling + RI vi + v R1 R2 gmv - (b) ro R RD vo 3 C2 − Bypass - C3 − Coupling 13.42(a) Figure P13.12 M1 + RI vi RD R 1 R vo 3 - (a) (c ) r o - RI vi (b) R v 1 + + gmv RD R 3 v - o C1 − Coupling C2 − Coupling 13.43 RI: Thévinen equivalent source resistance; R1: base bias voltage divider; R2: base bias voltage divider; RE and R4: emitter bias resistors - determine the emitter current; RC: collector bias resistor - sets the collector-emitter voltage; R3: load resistor 13.44 RI: Thévinen equivalent source resistance; R1: gate bias voltage divider; R2: gate bias voltage divider; R4: source bias resistor - sets source current; RD: drain bias resistor - sets drain-source voltage; R3: load resistor 13-14 13.45 RI: Thévinen equivalent source resistance; R1: base bias voltage divider; R2: base bias voltage divider; RE: emitter bias resistor - determines the emitter current; RC: collector bias resistor - sets the collector-emitter voltage; R3: load resistor 13.46 (a) r = (b) I = 0 rd = d D ⎛ ⎛ 0.6 ⎞ ⎞ 0.025 | I D = 10−14 ⎜ exp⎜ = 94.4 Ω ⎟ − 1⎟ = 264.9µA | rd = 264.9µA + 10 fA ⎝ ⎝ 0.025 ⎠ ⎠ VT ID + IS VD < VT ln 0.025 0.025 = 2.50 TΩ (c) > 1015 → I D + I S < 2.5 x10−17 A ID + IS 10 fA ID + IS 2.5x10−17 = 0.025ln = −0.150 V IS 10−14 13.47 kT 1.38x10−23 V = T = 8.63x10−5 T | rd ≅ T = 1000VT VT = −19 ID q 1.60x10 T VT rd 13.48 ⎛ 0.005 ⎞ 75K 6.47 mV 6.47 Ω (a) exp⎜⎝ 0.025⎟⎠ −1 = 0.221 100K 8.63 mV 8.63 Ω | ⎛ 0.005 ⎞ exp⎜− ⎟ −1 = −0.181 ⎝ 0.025 ⎠ ⎛ 0.010 ⎞ (b) exp⎜⎝ 0.025 ⎟⎠ −1 = 0.492 | ⎛ 0.010 ⎞ exp⎜− ⎟ −1 = −0.330 ⎝ 0.025 ⎠ 200K 17.3 mV 17.3 Ω 300K 25.9 mV 25.9 Ω 400K 34.5 mV 34.5 Ω 0.005 = 0.200 → +10.7% error 0.025 | − 0.005 = −0.200 → −9.37% error 0.025 0.010 = 0.400 → +23.0% error 0.025 | − 0.010 = −0.400 → −17.5% error 0.025 13.49 g m 0.03 = = 0.750 mA = 750 µA 40 40 g m 50x10−6 c I = ( ) C 40 = 40 = 1.25 µA (a) IC = (b) IC = g m 250x10−6 = = 6.25 µA 40 40 13-15 13.50 IC = β oVT rπ = 75(0.025V ) 10 4 Ω = 187.5 µA | Q - point : (188 µA,VCE ≥ 0.7 V ) ( ) g m = 40IC = 40 1.875x10−4 = 7.50 mS | ro = 13.51 IC = β oVT rπ = 125(0.025V ) = 1.56 µA | Q - point : (1.56 µA,VCE ≥ 0.7 V ) 2x106 Ω ( ) g m = 40IC = 40 1.56x10−6 = 62.4 µS | ro = 13.52 IC = β oVT rπ = 100(0.025V ) 250kΩ ( ) IC = β oVT rπ = 75(0.025V ) 106 Ω ( VA + VCE VA 75V ≅ = = 48.1 MΩ IC IC 1.56 µA = 10 µA | Q - point : (10 µA,VCE ≥ 0.7 V ) g m = 40IC = 40 10−5 = 0.400 mS | ro = 13.53 VA + VCE VA 100V ≅ = = 10 MΩ IC IC 10µA = 1.875 µA | Q - point : (1.88 µA,VCE ≥ 0.7 V ) ) g m = 40IC = 40 1.875x10−6 = 75.0 µS | ro = 13-16 VA + VCE VA 100V ≅ = = 533 kΩ IC IC 187.5 µA VA + VCE VA 100V ≅ = = 53.3 MΩ IC IC 1.875 µA 13.54 V + VCE ro = A ; solving for VA : VA = IC ro − VCE IC Using the values from row 1: VA = 0.002(40000)−10 = 70 V Using the values from the second row : β o = g mrπ = 0.12(500)= 60 and β F = β o = 60. Row 1: g m = 40IC = 40(0.002) = 0.08 S | rπ = µ f = g mro = 0.08(40000) = 3200 Row 2 : IC = βo gm = 60 = 750 Ω 0.08 g m 0.12 V + VCE 80 = = 3 mA | ro = A = = 26.7 kΩ 40 IC 40 0.003 µ f = g mro = 0.12(26700) = 3200 Row 3 : g m = ro = βo rπ = 60 g m 1.25 x 10-4 -4 = 1.25 x 10 S | I = = = 3.13 µA C 40 40 4.8 x 105 VA + VCE 80 = = 25.6 MΩ | µ f = g mro = 1.25 x 10-4 25.6 x 106 = 3200 IC 3.13 x 10-6 13.55 ( ⎛ 0.005 ⎞ (a) exp⎜⎝ 0.025⎟⎠ −1 = 0.221 | ) 0.005 = 0.200 → +10.7% error 0.025 ⎛ 0.005 ⎞ 0.005 = −0.200 → −9.37% error exp⎜− ⎟ −1 = −0.181 | − 0.025 ⎝ 0.025 ⎠ ⎛ 0.0075⎞ 0.0075 (b) exp⎜⎝ 0.025 ⎟⎠ −1 = 0.350 | 0.025 = 0.300 → +16.7% error ⎛ 0.0075 ⎞ 0.0075 = −0.300 → −13.6% error exp⎜− ⎟ −1 = −0.259 | − 0.025 ⎝ 0.025 ⎠ ⎛ 0.0025 ⎞ 0.0025 (c) exp⎜⎝ 0.025 ⎟⎠ −1 = 0.105 | 0.025 = 0.100 → +5.17% error ⎛ 0.0025 ⎞ 0.0025 = −0.100 → −4.84% error exp⎜− ⎟ −1 = −0.0952 | − 0.025 ⎝ 0.025 ⎠ 13.56 (a) β F = IC 350µA ∆I 600µA −125µA ≅ ≅ 90 | β o = C ≅ ≅ 120 4µA 6µA − 2µA IB ∆I B (b) β F ≅ 750µA 900µA − 600µA ≅ 95 | β o ≅ ≅ 75 8µA 4µA 13.57(a) 13-17 t=linspace(0,.004,1024); ic=.001*exp(40*.005*sin(2000*pi*t)); IC=fft(ic); z=abs(IC(1:26)/1024); z(1) ans = 0.001 plot(t,ic) x10-3 1.2 1 0.8 0 1 2 3 4 x10-3 z([5 9 13]) ans = 0.0001 0.0000 0.0000 13.57(b) t=linspace(0,.004,1024); ic=.001*exp(40*.005*sin(2000*pi*t)); IC=fft(ic); z=abs(IC(1:26)/1024); z(1) ans = 0.0023 plot(t,ic) -3 8 x10 6 4 2 0 0 1 z([5 9 13]) ans = 0.0016 0.0007 0.0002 13-18 2 3 4 x10-3 13.58 (a) NAME Q1 MODEL NBJT IB 2.21E-05 IC 1.78E-03 VBE 7.28E-01 VBC -5.41E+00 VCE 6.14E+00 BETADC 8.04E+01 GM 6.87E-02 RPI 1.17E+03 RX 0.00E+00 RO 4.52E+04 BETAAC 8.04E+01 T = 27 o C | VT = 8.625x10−5 (300) = 25.9mV IC 1.78mA = = 68.7 mS VT 25.9mV ⎛ V ⎞ ⎛ 6.14 ⎞ β o = β FO ⎜1+ CE ⎟ = 75⎜1+ ⎟ = 81.1 ⎝ 75 ⎠ ⎝ VA ⎠ β 81.1 = 1180 Ω rπ = o = gm 0.0687 gm = ro = VA + VCE 75 + 6.14 = = 45.6 kΩ IC 1.78mA 13 - 19 13.58(b) MODEL PBJT IB -2.69E-06 IC -3.73E-04 VBE -6.88E-01 VBC 1.99E+00 VCE -2.68E+00 BETADC 1.39E+02 GM 1.44E-02 RPI 9.61E+03 RX 0.00E+00 RO 2.06E+05 BETAAC 1.39E+02 T = 27 o C | VT = 8.625x10−5 (300) = 25.9mV IC 0.373mA = = 14.4 mS VT 25.9mV ⎛ V ⎞ ⎛ 2.68 ⎞ β o = β FO ⎜1+ CE ⎟ = 135⎜1+ ⎟ = 140 ⎝ 75 ⎠ ⎝ VA ⎠ gm = rπ = ro = βo gm = 140 = 9.72 kΩ 0.0144 VA + VCE 75 + 2.68 = = 208 kΩ IC 0.373mA Note: The SPICE model actually is using VCB instead of VCE in the current gain calculations. ⎛ ⎝ (a) β o = 75⎜1+ 13-20 5.41⎞ ⎟ = 80.4 75 ⎠ ⎛ ⎝ (b) β o = 135⎜1+ 1.99 ⎞ ⎟ = 139 75 ⎠ 13.59 ix + rπ y 11 v - gm v re vx ro ie αo ie 1 rπ v v 1− α o For the T - model : ix = x − α o x = vx re re re For the hybrid pi model: y11 = y11 = re = ix 1− α o = = vx re 1− βo βo + 1 re = 1 → r = (β o + 1)re (β o + 1)re π rπ βo α αV V = = o= o T = T IE (β o + 1) gm (β o + 1) gm IC 13.60 g m = 40(50µA) = 2.00mS | rπ = 100 75V + 10V = 50kΩ | ro = = 1.70 MΩ 2.00mS 50µA RBB = RB rπ = 100kΩ 50kΩ = 33.3kΩ ⎛ ⎞ 33.3kΩ Av = −⎜ ⎟(2mS ) 1.70 MΩ 100kΩ 100kΩ = −95.0 ⎝ 33.3kΩ + 0.75kΩ ⎠ ( ) 13.61 For β o = 100, see Prob. 13.60. 60 = 30kΩ | RBB = RB rπ = 100kΩ 30kΩ = 23.1kΩ 2.00mS ⎛ ⎞ 23.1kΩ Av = −⎜ ⎟(2mS ) 1.70 MΩ 100kΩ 100kΩ = −94.1 ⎝ 23.1kΩ + 0.75kΩ ⎠ −95.0 ≤ Av ≤ −94.1 − only a small variation rπ = ( ) 13.62 75 50 + 7.5 V = 750Ω | ro = = 23.0kΩ 2.5 mA 0.1S = RB rπ = 4.7kΩ 750Ω = 647Ω g m = 40(2.5mA)= 0.100S | rπ = RBB ⎛ 647Ω ⎞ Av = ⎜ ⎟(−0.100S ) 23.0kΩ 4.3kΩ 10kΩ = −247 ⎝ 50Ω + 647Ω ⎠ ( ) 13-21 13.63 g m = 40(1µA)= 40µS | rπ = 40 50 + 1.5 V = 1MΩ | ro = = 51.5MΩ µA 40µS 1 RBB = RB rπ = 5MΩ 1MΩ = 833kΩ ⎛ ⎞ 833kΩ Av = ⎜ ⎟(−40µS ) 51.5MΩ 1.5MΩ 3.3MΩ = −40.0 ⎝10kΩ + 833kΩ ⎠ ( ) 13.64 SPICE Results: IC = 248 µA, VCE = 3.30 V, AV = -15.1 dB -- IC differs by 1.2% - AV is off by 0.5% 13.65 [10(V )] = [10(9)] N CC N ≥ 20000 → N ≥ log(20000) log(90) = 2.20 → N = 3 (or quite possibly 2 by droping a larger fraction of the supply voltage across RC ) 13.66 *Problem 13.21 - PNP Common-Emitter Amplifier - Figure P13.5 VCC 7 0 DC 9 VI 1 0 AC 1 RI 1 2 1K C1 2 3 100U R1 7 3 20K R2 3 0 62K RE 7 4 3.9K C 7 4 100U RC 5 0 13K C3 5 6 100U R3 6 0 100K Q1 5 3 4 PBJT .OP .MODEL PBJT PNP IS=1E-15 BF=135 VA=75 .AC DEC 10 100Hz 10000Hz .PRINT AC VM(6) VDB(6) VP(6) .END Results: IC = 373 µA, VEC = 2.68V, AV = -134 Hand calculations in Prob. 13.21 yielded (371 µA, 2.72V) 135 = 9.12kΩ | ro = ∞ 14.8mS RB = R1 R2 = 20kΩ 62kΩ = 15.1kΩ | RBB = 15.1kΩ 9.12kΩ = 5.69kΩ gm = 40(371µA) = 14.8mS | rπ = ⎛ 5.69kΩ ⎞ Av = −⎜ ⎟(14.8mS ) ∞ 13kΩ 100kΩ = −145 ⎝ 1kΩ + 5.69kΩ ⎠ ( 13-22 ) SPICE AV result is somewhat lower because ro is included. 13.67 Av ≅ −10VCC = −10(12) = −120 13.68 Av ≅ −10(VCC + VEE ) = −10(15 + 15) = −300 13.69 Av = −10(VCC + VEE )= −10(1.5 + 1.5)= −30; This estimate says no. However, if we look a bit deeper, Av = −40(IC RC ) = −40VRC ,and we let VRC = then we can achieve A v = −40(1.5)= −60. (V CC + VEE ) 2 = 1.5V , So, with careful design, we can probably achieve a gain of 50. 13.70 Using our rule - of - thumb estimate, 1 = −10 Av ≅ −10VCC = −10(1.5)= −15 | Av = −10() Note that this result assumes that IC varies with VCC. 13.71 5V (a) i = 10kΩ = 0.5 mA, but i ≤ 0.2I for small - signal operation. (b) V ≥ V + i R + I R = 0.7 + 5 + 25 = 30.7 V c CC c BE c L C C So IC ≥ 5ic = 2.5 mA. L 13.72 Av = 40dB = 100 | v o = 100v be = 100(0.005V ) = 0.500V . 13-23 13.73 For common - emitter stage : Av = 50dB → Av = −316 15V = 47.5mV which is far too big for small- signal operation. 316 The will be significant distortion of the sine wave. vbe = 13.74 20kΩ 18 = −4.61V | REQ = 20kΩ 62kΩ = 15.1kΩ 62kΩ + 20kΩ −4.61− 0.7 − (−9) = 6.76µA | IC = 135I B = 913µA IB = 15.1kΩ + 136(3.9kΩ) (a) V EQ = −9 + VCE = 9 −13000IC − 3900I E − (−9) = 2.54V g m = 40IC = 0.0365S | rπ = 135 = 3.70kΩ | ro = ∞ | R L = 13kΩ 100kΩ = 11.5kΩ gm ⎛ 2.97kΩ ⎞ Av = −⎜ ⎟(0.0365)(11.5kΩ)= −314 ⎝ 1kΩ + 2.97kΩ ⎠ (b) For V CC = 18V , the answers are the same : IC = 913µA | VEC = 2.54V | Av = −314 13.75 Using the information from Row 1: 1 λ ( )( ) = I D ro − VDS = 8x10−4 4x10 4 − 6 = 26V ; λ = 0.0385V -1 gm2 From Row 2 : K n = = 2ID (1+ λVDS ) (2x10 ) = 3.25x10 ⎛ 6⎞ 2(5x10 )⎜1+ ⎟ ⎝ 26 ⎠ −4 2 −4 −5 A V2 ⎛ 6⎞ Row 1: gm = 2K n ID (1+ λVDS ) = 2(3.25x10−4 )(8x10−4 )⎜1+ ⎟ = 8x10−4 S ⎝ 26 ⎠ µ f = gm ro = 8x10−4 (4 x10 4 )= 32 2ID = 0.2 0.2(VGS − VTN ) = 0.2 K n (1+ λVDS ) 13-24 2(8x10−4 ) = 0.40V 6⎞ −4 ⎛ 3.25x10 ⎜1+ ⎟ ⎝ 26 ⎠ 1 Row 2 : ro = λ + VDS ID = 26 + 6 = 640kΩ | µ f = gm ro = 2x10−4 (6.4 x10 5 )= 128 −5 5x10 2(5x10−5 ) = 0.10V 6⎞ −4 ⎛ 3.25x10 ⎜1+ ⎟ ⎝ 26 ⎠ ⎛ 6⎞ Row 3 : gm = 2K n ID (1+ λVDS ) = 2(3.25x10−4 )(10−2 )⎜1+ ⎟ = 2.83x10−3 S ⎝ 26 ⎠ 2ID 0.2(VGS − VTN ) = 0.2 = 0.2 K n (1+ λVDS ) 1 ro = λ + VDS = ID 26 + 6 = 3.2kΩ | µ f = gm ro = 2.83x10−3 (3.2x10 3 )= 9.06 0.01 0.2(VGS − VTN ) = 0.2 2ID = 0.2 K n (1+ λVDS ) 2(10−2 ) = 1.41V 6⎞ −4 ⎛ 3.25x10 ⎜1+ ⎟ ⎝ 26 ⎠ MOSFET Small-Signal Parameters ID (S) gm (Ω) ro µf Small-Signal Limit vgs (V) 0.8 mA 0.0008 40,000 32 0.40 50 µA 0.0002 640,000 128 0.10 10 mA 0.00283 3200 9.06 1.41 13.76 ⎛1 ⎞ 2Kn (1+ λVDS ) ⎛ 1 ⎞ 2Kn ⎛ 1 ⎞ 2Kn' ⎛ W ⎞ µ f = ⎜ + VDS ⎟ ≅⎜ ⎟ =⎜ ⎟ ⎜ ⎟ ID ⎝λ ⎝ λ ⎠ ID ⎝ λ ⎠ ID ⎝ L ⎠ ⎠ 2 2x10-4 2 I W 50 = (µ f λ ) D ' = 250(0.02) = L 1 2Kn 2 5x10-5 [ VGS − VTN ] ( ( ( ) ) ) 2 2x10-4 2I D ≅ = = 0.160 V Kn 50 5x10-5 13-25 13.77 −4 ⎛1 ⎞ 2K n (1+ λVDS ) ⎛ 1 ⎞ 2K n ⎛ 1 ⎞ 2(2.5x10 ) µ f = ⎜ + VDS ⎟ ≅⎜ ⎟ | ⎜ ⎟ ≤ 1 → ID ≥ 1.25 A ⎝λ ⎠ ⎝ λ ⎠ ID ⎝ .02 ⎠ ID ID 13.78 gm = 2I D VGS − VTN | ID = (.005)(0.5) = 1.25 mA 2 | 2(1.25mA) 250 W 2I D = = = 2 L K ' (V − V ) 4x10−5 (0.5)2 1 n GS TN 13.79 2 (1+ 0.2) −1 = 0.44 | 2(0.2) = 0.40 →10% error (1+ 0.4) 2 −1 = 0.96 | 2(0.4) = 0.80 → 20% error 13.80 From the results of Problem 13.24: ID = 8.29E-05, VGS = 1.81E+00, VDS=5.96E+00, GM = 2.04E-04, GDS = 0.00E+00 gm = 2(82.9µA) 2I D 1 = = 205 µS | λ = 0 → ro = ∞ | g ds = = 0 VGS − VTN 1.81−1 ro 13.81 From the results of Problem 13.28: ID = 3.07E-04, VGS = -2.24E+00, VDS=-3.86E+00, GM = 4.96E-04, GDS = 0.00E+00 2(307µA) 2I D 1 = = 495 µS | λ = 0 → ro = ∞ | g ds = = 0 ro VGS − VTP −2.24 + 1 gm = 13.82 Rout = ID = RD ro V 9V 50V + 9V 7.8V | Using VDS = DD | RD = | ro = → Rout = RD + ro 2 ID ID ID 7.8V = 156µA → RD = 57.6kΩ | ro = 378kΩ | Q - point : (156 µA, 9 V ) 50kΩ 13.83 Virtually any Q-point is possible. RIN is set by RG which can be any value desired since there is no gate current. (Note this is not the case with a BJT for which base current must be considered.) 13-26 13.84 Note that iG ≅ 0 for this device. Load line : 400 = 133000iP + v PK and vGK = −1.5V Two points (i P , v PK ) : (3mA, 0V) and (0mA, 400V) → Q - pt : (1.4 mA, 215 V) ro = 250V − 200V 2.3mA − 0.7mA = 55.6kΩ | g m = = 1.6mS | µ f = 89.0 2.15mA −1.25mA −1V − (−2V ) ( ) ( ) Av = −g m RP ro = −1.6mS 133kΩ 55.6kΩ = −62.7 13.85 gm2 (0.5S) = 5 A! BJT : IC = gmVT = 0.5S (0.025V ) = 12.5mA | MOSFET : ID = = 2K n 2(25mA /V 2 ) 2 The BJT can achieve the required transconductance at a 400 times lower current than the MOSFET. For a given power supply voltage, the BJT will therefore use 400 times less power. 60 = 120Ω (versus ∞ for the FET). Note, however, that rπ is small for the BJT: rπ = 0.5 13.86 Since a relatively high input resistance is required at a relatively high current, a FET should be used. If a BJT were selected, it would be very difficult to achieve the required input resistance because its value of rπ is low: β V 100(.025V ) rπ = o T = = 250 Ω IC 10mA 13.87 ⎛1 ⎞ 2Kn (1+ λVDS ) 40(VA + VCE )= ⎜ + VDS ⎟ ID ⎝λ ⎠ 40(35) = 60 2(0.025)(1.2) ID → I D = 111 µA | µ f = 40(35) = 1400 13.88 V I µ f ≅ A = 40VA = 40(50)= 2000 | g m = C = 40IC = 40 2x10−4 = 8.00 mS VT VT ( ) ( ) 2 2x10−4 2 2 2I D µf ≅ = = 200 | g m = = = 0.800 mS VGS − VTN 0.5 λ(VGS − VTN ) 0.02(0.5) 13-27 13.89 Either transistor could be used. For a BJT operating in the common-emitter configuration or an FET operating in the common-source configuration: 100(0.025V ) = 33.3 mA - A fairly high current rπ 75Ω For the FET : Rin = RG and setting RG = 75 Ω is satisfactory, particularly if a depletion mode FET is available. The input of a CE circuit operating at a much lower current could also be swamped by the addition of a 75-Ω resistor in parallel with its input. (Note that common-base and common-gate amplifiers from Chapter 14 could also be used.) For the BJT : Rin ≅ rπ | BJT : IC = β oVT = 13.90 26 (a) Av = 10 20 = 20.0. Either a BJT or MOSFET can achieve the required gain. However, based upon the material in Chapter 13, an FET should be chosen since the input voltage of 0.25 V is 50 time larger than the permissible value for vbe (0.005 V) for the BJT. For the FET, a value of VGS – VTN = 1.25 V will satisfy the small-signal limit with vgs = 0.25 V. (The generalized commonemitter stage with emitter degeneration can also satisfy the requirements.) (b) The FET is also best for this case, since the amplifier will see input signals much greater than the 5-mV limit of the BJT. 13.91 Av ≅ − (12) = −12 or 21.6 dB VDD =− VGS − VTN 1 13.92 15 7.5V vd = = 7.5V peak | 15dB → Av = −5.62 | vgs = = 1.34V | VGS − VTN ≥ 5(1.34)= 6.70V 2 5.62 Yes, it is possible although the required value of (VGS − VTN ) is getting rather large. 13.93 Av ≅ VDD VGS − VTN | 9 ≥ 30 → VGS − VTN ≤ 0.300 V VGS − VTN 13.94 For VDS = ID = VDD VDD , Av = − 2 VGS − VTN | 30 = 15 VGS − VTN | VGS − VTN = 0.5 V 2 1mA VGS − VTN ) = 125 µA | Q - point : (125 µA,7.5 V ) ( 2 13-28 13.95 0.1 = 0.5V 0.2 Av = 35dB → Av = −56.2. Using the rule - of - thumb estimate to select VDD : vgs ≤ 0.2(VGS − VTN ) requires (VGS − VTN ) ≥ Av = − and VDD = 56.2(0.5V )= 28 V VDD VGS − VTN 13.96 0.5 = 2.5V 0.2 Av = 20dB → Av = −10. Using the rule - of - thumb estimate to select VDD : vgs ≤ 0.2(VGS − VTN ) requires (VGS − VTN ) ≥ Av = − and VDD = 10(2.5) = 25 V VDD VGS − VTN 13.97 ⎛ VDD ⎞ N ⎛ 10 ⎞ N We desire ⎜ ⎟ ≥ 1000 | ⎜ ⎟ ≥ 1000 ⎝ VGS − VTN ⎠ ⎝ VGS − VTN ⎠ For VGS − VTN = 1 V , N = 3 meets the requirements, but with no safety margin. For VGS − VTN = 0.75 V , N = 3 easily meets the requirements. 13.98 For the bias network : VEQ = 10V 430kΩ = 4.343V | REQ = 430kΩ 560kΩ = 243kΩ 430kΩ + 560kΩ 2 5x10−4 VGS −1) | VGS = 4.343 − 2x10 4 I D → VGS = 1.72 V | I D = 131 µA ( 2 = 10 − 63kΩ(131µA)= 1.75V ≥ VGS − VTN so active region assumption is ok. ID = VDS ⎛ 1 ⎞ + 1.75⎟ ⎜ ⎝ 0.0133 ⎠ g m = 2 5x10−4 (131µA) = 362µS | ro = = 586kΩ 131µA 243kΩ Av = − (362µS ) 586kΩ 43kΩ 100kΩ = −10.3 243kΩ + 1kΩ ( ) ( ) 13.99 ⎛ µA ⎞ 50 + 5V g m = 2⎜ 500 2 ⎟(100µA)(1+ 0.02(5)) = 332µS | ro = = 550kΩ 100µA V ⎠ ⎝ ⎛ ⎞ 6.8 MΩ Av = −⎜ ⎟(332µS ) 550kΩ 50kΩ 120kΩ = −10.9 ⎝ 6.8 MΩ + 0.1MΩ ⎠ ( ) 13-29 13.100 ( ) ( ) g mmax = 2 700µA/V 2 (100µA) = 374µS | g mmin = 2 300µA/V 2 (100µA) = 245µS ⎛ ⎞ 6.8 MΩ Av = −⎜ ⎟(g m ) 550kΩ 50kΩ 120kΩ = (−32.7kΩ)(g m ) ⎝ 6.8 MΩ + 0.1MΩ ⎠ ( ) Avmax = −12.2 | Avmin = −8.01 13.101 ( ) g m = 2 100µA/V 2 (10µA)(1+ 0.02(5)) = 46.9µS | ro = 50 + 5V = 5.50 MΩ 10µA ⎛ ⎞ 10 MΩ Av = −⎜ ⎟(46.9µS ) 5.50 MΩ 560kΩ 2.2 MΩ = −19.2 ⎝ 10 MΩ + 0.1MΩ ⎠ ( 13.102 ) ( ) g m = 2Kn I DS (1+ λVDS ) = 2(0.001)(0.002) 1+ 0.015(7.5) = 2.11x10−3 S 1 ro = λ + VDS I DS ( 1 + 7.5 0.015 = = 37.1kΩ 0.002 ) ( ) Avt = −g m ro RD R3 = −2.11x10−3 37.1kΩ 3.9kΩ 270kΩ = −7.35 Av = 10 MΩ Avt = −7.34 10kΩ + 10 MΩ 13-30 13.103 *Problem 13.103 - NMOS Common-Source Amplifier - Figure P13.6 VDD 7 0 DC 15 *FOR OUTPUT RESISTANCE *VO 6 0 AC 1 *VI 1 0 AC 0 VI 1 0 AC 1 RI 1 2 1K C1 2 3 100UF R1 3 0 1MEG R2 7 3 2.7MEG R4 4 0 27K C2 4 0 100UF RD 7 5 82K C3 5 6 100UF R3 6 0 470K M1 5 3 4 4 NFET .OP .MODEL NFET NMOS KP=250U VTO=1 .AC LIN 1 1000 1000 .PRINT AC VM(6) VDB(6) VP(6) IM(VI) IP(VI) *.PRINT AC IM(C3) IP(C3) .END Results: ID = 8.29E-05 VGS = 1.81E+00 VDS = 5.96E+00 VM(6) = 1.420E+01 VP(6) = -1.800E+02 IM(VI) = 1.369E-06 IP(VI) = -1.800E+02 VM(3) = 9.986E-01 VP(3) = 1.248E-04 IM(C3) = 1.220E-05 IP(C3) = -1.800E+02 Av = −14.6 | Rin = VM (3) 0.9986 1 1 = = 729 kΩ | Rout = = = 82.0 kΩ IM (C3) 12.20µA IM (VI ) 1.369µA 13-31 13.104 *Problem 13.104 - PMOS Common-Source Amplifier - Figure P13.8 VDD 7 0 DC 18 *FOR OUTPUT RESISTANCE *VO 6 0 AC 1 *VI 1 0 AC 0 * VI 1 0 AC 1 RI 1 2 1K C1 2 3 100U R2 7 3 3.3MEG R1 3 0 3.3MEG R4 7 4 22K C2 7 4 100U RD 5 0 24K C3 5 6 100U R3 6 0 470K M1 5 3 4 4 PFET .OP .MODEL PFET PMOS KP=400U VTO=-1 .AC LIN 1 1000 1000 .PRINT AC VM(6) VDB(6) VP(6) IM(VI) IP(VI) VM(3) VP(3) *.PRINT AC IM(C3) IP(C3) .END Results: ID = 3.07E-04 VGS = -2.24E+00 VDS = -3.86E+00 VM(6) = 12.76E+01 VP(6) = -1.799E+02 IM(VI) = 6.057E-07 IP(VI) = -1.800E+02 VM(3) = 9.994E-01 VP(3) = 5.523E-05 IM(C3) = 4.167E-05 Av = −12.8 | Rin = 13-32 IP(C3) = -1.800E+02 VM (3) 0.9994V 1 1 = = 1.65 MΩ | Rout = = = 24.0 kΩ IM (C3) 41.67µA IM (VI ) 0.6057µA 13.105 *Problem 13.105 - Depletion-mode NMOS Common-Source Amplifier - Figure P13.11 VDD 7 0 DC 18 *FOR OUTPUT RESISTANCE *VO 6 0 AC 1 *VI 1 0 AC 0 * VI 1 0 AC 1 RI 1 2 10K C1 2 3 100UF RG 3 0 10MEG R1 4 0 2K C3 4 0 100UF RD 7 5 3.9K C2 5 6 100UF R3 6 0 36K J1 5 3 4 NFET .OP .MODEL NFET NMOS KP=400U VTO=-5 .AC LIN 1 1000 1000 .PRINT AC VM(6) VDB(6) VP(6) IM(VI) IP(VI) VM(3) VP(3) *.PRINT AC IM(C2) IP(C2) .END Results: ID = 1.25E-03 VGS = -2.50E+00 VDS = -1.06E+01 VM(6) = 3.515E+00 VP(6) = -1.799E+02 IM(VI) = 9.991E-08 IP(VI) = -1.800E+02 VM(3) = 9.990E-01 VP(3) = 9.106E-06 IM(C3) = 2.564E-04 IP(C3) = -1.800E+02 Av = −3.52 | Rin = VM (3) 0.9990V 1 1 = = 10.0 MΩ | Rout = = = 3.90 kΩ IM (C3) 256.4 µA IM (VI ) 99.91nA 13.106 SPICE Results: Q-point: (1.01 mA, 7.41 V), Av = 15.1 dB, Rin = 2.20 MΩ, Rout = 7.50 kΩ 13.107 g m = 40(50µA) = 2.00mS | rπ = 100 75V + 10V = 50kΩ | ro = = 1.70 MΩ 50µA 2.00mS Rin = RB rπ = 100kΩ 50kΩ = 33.3kΩ | Rout = 1.7 MΩ 100kΩ = 94.4kΩ 13-33 13.108 Rin = RB rπ | rπmin = 60 100 = 30kΩ | rπmax = = 50kΩ 40(50µA) 40(50µA) Rinmin = RB rπ = 100kΩ 30kΩ = 23.1kΩ | Rinmax = RB rπ = 100kΩ 50kΩ = 33.3kΩ Rout = RC ro = 100kΩ 75 + 10 = 100kΩ 1.7 MΩ = 94.4kΩ independent of βo 50µA 13.109 40(0.025V ) 50 + 1.5 V = 1.00 MΩ | ro = = 51.5MΩ rπ = 1 1µA µA Rin = RB rπ = 5MΩ 1MΩ = 833 kΩ | Rout = RC ro = 1.5MΩ 51.5MΩ = 1.46 MΩ 13.110 75(0.025V ) 50 + 7.5 V rπ = = 750Ω | ro = = 23.0kΩ 2.5mA 2.5 mA Rin = RB rπ = 4.7kΩ 0.75kΩ = 647 Ω | Rout = RC ro = 4.3kΩ 23kΩ = 3.62kΩ 13.111 From Prob. 13.98 : Q - Point = (131µA, 1.75V) Rin = R1 R2 = 430kΩ 560kΩ = 243 kΩ | Rout = 43kΩ ro ⎛ 1 ⎞ + 1.75⎟V ⎜ ⎝ 0.0133 ⎠ ro = = 587kΩ | Rout = 43kΩ 587kΩ = 40.1kΩ 0.131mA 13.112 Rin = RG = 6.8 MΩ | Rout = 50kΩ ro ro = (50 + 5)V = 550kΩ 0.1mA | Rout = 50kΩ 550kΩ = 45.8kΩ 13.113 Rin = RG = 6.8 MΩ which is independent of Kn | Rout = RD ro ⎛ 1 ⎞ + 5⎟V ⎜ ⎝ 0.02 ⎠ ro = = 550kΩ | Rout = 50kΩ 550kΩ = 45.8 kΩ, also independent of Kn 0.1mA 13-34 13.114 Rin = RG = 10 MΩ | Rout = RD ro ⎛ 1 ⎞ + 5⎟V ⎜ ⎝ 0.02 ⎠ | ro = = 5.50 MΩ 10µA Rout = 560kΩ 5.50 MΩ = 508 kΩ 13.115 ⎛ 1 ⎞ + 7.5⎟V ⎜ ⎝ 0.015 ⎠ | ro = = 37.1 kΩ 2mA Rin = RG = 1MΩ | Rout = RD ro Rout = 3.9kΩ 37.1kΩ = 3.53 kΩ 13.116 g m = 40(50µA) = 2.00mS | rπ = 100 75V + 10V = 50kΩ | ro = = 1.70 MΩ 2.00mS 50µA RBB = RB rπ = 100kΩ 50kΩ = 33.3kΩ ⎛ ⎞ 33.3kΩ vth = −vi ⎜ ⎟(2mS ) 1.70 MΩ 100kΩ = −185vi ⎝ 33.3kΩ + 0.75kΩ ⎠ ( ) Rth = 1.70 MΩ 100kΩ = 94.4 kΩ 13.117 75 50V + 7.5V = 750Ω | ro = = 23.0kΩ 100mS 2.5mA = RB rπ = 4.7kΩ 0.75kΩ = 647Ω g m = 40(2.5mA) = 100mS | rπ = RBB ⎛ 647Ω ⎞ vth = −vi ⎜ ⎟(100mS ) 23.0kΩ 4.3kΩ = −336v i ⎝ 647Ω + 50Ω ⎠ ( ) Rth = 23.0kΩ 4.3kΩ = 3.62 kΩ 13.118 ( ) g m = 2 500µA/V 2 (100µA)(1+ 0.02(5)) = 332µS | ro = (50 + 5)V = 550kΩ 100µA ⎛ ⎞ 6.8 MΩ vth = −vi ⎜ ⎟(332µS ) 550kΩ 50kΩ = −15.0vi ⎝ 6.8 MΩ + 0.1MΩ ⎠ ( ) Rth = 550kΩ 50kΩ = 45.8 kΩ 13-35 13.119 ( ) g m = 2 100µA/V 2 (10µA)(1+ 0.02(5)) = 46.9µS | ro = (50 + 5)V = 5.50 MΩ 10µA ⎛ ⎞ 10 MΩ vth = −vi ⎜ ⎟(46.9µS ) 5.50 MΩ 560kΩ = −23.6vi ⎝10 MΩ + 0.1MΩ ⎠ ( ) Rth = 5.50 MΩ 560kΩ = 508 kΩ 13.120 SPICE Results: Q-point: (242 µA, 3.61 V), Av = 31.1 dB, Rin = 14.8 kΩ, Rout = 9.81 kΩ 13.121 0 = 10000I B + 0.7 + 66(1615)I B − 5 I B = 36.9 µA | IC = 65I B = 2.40 mA VCE = 5 −1000IC −1615I E − (−5)= 3.66 V Q − point : (2.40 mA, 3.66 V ) 65 50V + 3.66V = 677 Ω | ro = = 22.4 kΩ 96.0mS 2.40mA Rin = RB rπ (1+ g m RE )= 10kΩ 677Ω 1+ 0.096(15) = 1.42 kΩ g m = 40(2.40mA)= 96.0mS | rπ = [ ] ⎛ ⎞ 96.0mS 1.42kΩ 1kΩ 220kΩ = −31.8 Av = −⎜ ⎟ ⎝ 0.33kΩ + 1.42kΩ ⎠ 1+ 0.096(15) ( [ ) ] Rout = 1kΩ 22.4kΩ 1+ 0.096(15) = 982 Ω 13.122 SPICE Results: Q-point: (2.39 µA, 3.69 V), Av = 29.7 dB, Rin = 1.49 kΩ, Rout = 977 Ω The results agree closely with the hand calculations in Prob. 13.121. The small disagreements arise from  m atu us in  13.123 0 = 106 I B + 0.7 + 66(161.5kΩ)I B − 5 I B = 0.369 µA | IC = 65I B = 24.0 µA VCE = 5 −1000IC −1615I E − (−5)= 3.66 V g m = 40(24.0µA) = 0.959mS | rπ = Q − point : (24.0 µA, 3.66 V ) 65 50V + 3.66V = 67.8 kΩ | ro = = 2.24 MΩ 0.959mS 24.0µA [ ] Rin = RB rπ (1+ g m RE )= 1MΩ 67.8kΩ 1+ 0.959mS (1.5kΩ) = 142 kΩ ⎛ ⎞ 0.959mS 142kΩ Av = −⎜ 100kΩ 220kΩ = −27.0 ⎟ ⎝ 0.33kΩ + 142kΩ ⎠ 1+ 0.959mS (1.5kΩ) ( [ ] Rout = 100kΩ 2.24 MΩ 1+ 0.959mS (1.5kΩ) = 98.2 kΩ 13-36 ) 13.124 SPICE Results: Q-point: (24.6 µA, 3.52 V), Av = 28.4 dB, Rin = 148 kΩ, Rout = 98.1 kΩ The results agree closely with the hand calculations in Prob. 13.123. The small disagreements arise from   m atu us in  13.125 SPICE Results: Q-point: (251 µA, 4.45 V), Av = 16.3 dB, Rin = 1.00 MΩ, Rout = 28.7 kΩ The results agree closely with the hand calculations in Ex. 13.10. 13.126 *Problem 13.126 - NMOS Common-Source Amplifier - Figure P13.98 VDD 7 0 DC 10 *FOR OUTPUT RESISTANCE *VO 6 0 AC 1 *VI 1 0 AC 0 * VI 1 0 AC 1 RI 1 2 1K C1 2 3 100U R1 3 0 430K R2 7 3 560K R4 4 0 20K C3 4 0 100U RD 7 5 43K C2 5 6 100U R3 6 0 100K M1 5 3 4 4 NFET .OP .MODEL NFET NMOS KP=500U VTO=1 LAMBDA=0.0133 .AC LIN 1 1000 1000 .PRINT AC VM(6) VDB(6) VP(6) VM(3) VP(3) IM(VI) IP(VI) *.PRINT AC IM(C2) IP(C2) .END Results: ID = 1.31E-04 VDS = 1.73E+00 VM(6) = 1.044E+01 VP(6) = -1.800E+02 IM(VI) = 4.094E-06 IP(VI) = -1.800E+02 VM(3) = 9.959E-01 VP(3) = 3.734E-04 IM(C3) = 2.496E-05 IP(C3) = -1.800E+02 Av = −10.4 | Rin = VM (3) 0.9959V 1 1 = = 243 kΩ | Rout = = = 40.1 kΩ IM (C3) 24.96µA IM (VI ) 4.094 µA 13-37 13.127 I B = 3.71µA IC = 241µA I E = 245µA VCE = 3.67V PR B = I B2 RB = (3.71µA) (100kΩ)= 1.38 µW | PRC = IC2 RC = (241µA) (10kΩ)= 0.581 mW 2 2 PR E = I E2 RE = (245µA) (16kΩ) = 0.960 mW 2 PBJT = ICVCE + I BVBE = (241µA)(3.67V )+ (3.71µA)(0.7V )= 0.887 mW PS = 5V (241µA)+ (−5V )(−245µA) = 2.43 mW | PS = PR B + PRC + PR E + PQ 13.128 I D = 250µA VDS = 4.75V PJFET = I DVDS = (250µA)(4.75V )= 1.19 mW | PR D = I D2 RD = (250µA) (27 kΩ)= 1.69 mW 2 PR 4 = I D2 R4 = (250µA) (2 kΩ) = 0.125 mW | PRG = 0 2 PS = 12V (250µA) = 3.00 mW | PJFET + PR D + PR 4 + PRG = 3.00 mW 13.129 Using the values from Prob. 13.17 : I B = 23.8µA IC = 1.78mA I E = 1.81mA VCE = 6.08V VB = −4.09V 2 2 V12 (−4.09 − ( −12)) V V22 (12 − ( −4.09)) V PR1 = = = 12.5 mW | PR 2 = = = 25.9 mW R1 5000Ω R2 10000Ω 2 2 PRC = IC2 RC = (1.78 mA) (6 kΩ) = 19.0 mW | PR E = I E2 RE = (1.81mA) (4 kΩ)= 13.0 mW 2 2 PBJT = ICVCE + I BVBE = (1.78 mA)(6.08V )+ (23.8µA)(0.7V ) = 10.8 mW ⎡ ⎡ 12 − ( −4.09)V ⎤ −4.09 − ( −12)V ⎤ PS = 12V ⎢1.78 mA + ⎥ + 12V ⎢1.81mA + ⎥ = 81.3 mW 10000Ω ⎦ 5000Ω ⎦ ⎣ ⎣ PS = PR1 + PR 2 + PRC + PR E + PBJT = 81.2 mW 13.130 Using the values from Prob. 13.19 : I B = 1.51µA IC = 98.4µA I E = 99.9µA VCE = 4.96V PR B = I B2 RB = (1.51µA) 3kΩ = 6.84 nW | PRC = IC2 RC = (98.4µA) (33kΩ)= 0.320 mW 2 2 PR E = I E2 RE = (99.9µA) (68 kΩ)= 0.679 mW 2 PBJT = ICVCE + I BVBE = (98.4µA)(4.96V )+ (1.51µA)(0.7V ) = 0.489 mW PS = 7.5(98.4µA)+ 7.5V (99.9µA)= 1.49 mW | PS = PR B + PRC + PR E + PBJT = 1.49 mW 13-38 13.131 Using the values from Prob. 13.23: I D = 82.2µA VDS = 6.04V PFET = I DVDS = (82.2µA)(6.04V ) = 0.497 mW | PR D = I D2 RD = (82.2µA) (82kΩ) = 0.554 mW 2 PR 4 = I D2 R4 = (82.2µA) (27kΩ)= 0.182 mW | I2 = 2 15V = 4.05µA 3.7 MΩ PR1 = I22 R1 = (4.05µA) (1MΩ)= 16.4 µW | PR 2 = I22 R2 = (4.05µA) (2.7 MΩ) = 44.3 µW 2 2 PS = 15V (82.2µA + 4.05µA)= 1.29 mW | PFET + PR D + PR 4 + PR1 + PR 2 = 1.29 mW 13.132 Using the values from Prob. 13.27 : I D = 307µA VSD = 3.88V PFET = I DVSD = (307µA)(3.88V ) = 1.19 mW | PR D = I D2 RD = (307µA) (24kΩ)= 2.26 mW 2 PR 4 = I D2 R4 = (307µA) (22kΩ) = 2.07 mW | I2 = 2 18V = 2.73µA 6.6 MΩ PR1 = I22 R1 = (2.73µA) (3.3MΩ) = 24.6 µW | PR 2 = I22 R2 = (2.73µA) (3.3MΩ)= 24.6 µW 2 2 PS = 18V (307µA + 2.73µA)= 5.58 mW | PFET + PR D + PR 4 + PR1 + PR 2 = 5.57 mW 13.133 Using the values from Prob. 13.33: I D = 1.25mA VDS = 10.6V PFET = I DVDS = (1.25mA)(10.6V ) = 13.3 mW | PR D = I D2 RD = (1.25mA) (3.9kΩ) = 6.09 mW 2 PR S = I D2 RS = (1.25mA) (1kΩ)= 1.56 mW | PR 4 = I D2 R4 = (1.25mA) (1kΩ) = 1.56 mW 2 PRG = IG2 RG = 0 13.134 V IC = CC 3RC 2 PS = 18V (1.25mA) = 22.5 mW | PFET + PR D + PR S + PR1 = 22.5 mW | ic ≤ 0.2IC | v c = ic RC ≤ 0.2 VCC V RC = CC 3RC 15 13.135 2 500x10−6 0 − (−1.5) = 563 µA 2 vgs ≤ 0.2(VGS − VTN )= 0.2 0 − (−1.5) = 0.3 V ( id ≤ 0.4I D | I D = ( ) ) vds = id RD ≤ 0.4(563µA)(15kΩ)= 3.38 V To insure saturation : vDS ≥ vGS − VTN = vgs − VTN = 0.3 − (−1.5) = 1.8 V VDD ≥ 1.8 + 3.38 + (563µA)(15kΩ)= 13.6 V 13.136 13-39 Assuming VCC >> VCESAT : 2 2 2 2 ⎛ VCC ⎞ VCC VCC 1 ⎛ VCC ⎞ 1 VCC | Pdc = VCC ⎜ | Pac = ⎜ = vo ≤ ⎟= ⎟ 2 ⎝ 2 ⎠ RL 8RL 2 ⎝ 2RL ⎠ 2RL 13.137 The Q - point from problem 13.21 is (371µA, 2.72V). ( ) ( 2 VCC 8R | ε = 100% 2 L = 25 % VCC 2RL ) vo ≤ g m vbe ro RC R3 = 40(371µA)(5mV ) ∞ 13kΩ 100kΩ = 0.854 V 13.138 The Q - point from Problem 13.23 is (82.2µA,6.04V ). ( ) ( ) id ≤ 0.4I D = 32.9µA | vds ≤ 0.4I D ro RD R3 = 32.9µA ∞ 82kΩ 470kΩ = 2.30V 13.139 The Q - point from Problem 13.27 is (307µA,3.88V ). ( ) ( ) id ≤ 0.4I D = 307µA | vo ≤ 0.4I D ro RL R3 = 307µA ∞ 24kΩ 470kΩ = 2.80V Checking the bias point : VR D = 307µA(24kΩ) = 7.37V | 2.80 < 7.37 & 2.80 < 3.88 -1 13.140 The Q - point from problem 13.17 is (1.78mA, 6.08V ). ( ) ( ) ic ≤ 0.2IC = 0.356 mA | vc ≤ 0.2IC ro RC R3 = 0.356mA ∞ 6kΩ 100kΩ = 2.02V 13.141 The Q - point from problem 13.33 is (1.25 mA, 10.6 V ). ( ) ( Neglecting ro , ) id ≤ 0.4I D = 0.500mA | vd ≤ 0.4I D RD R3 = 0.500mA 3.9kΩ 36kΩ = 1.76 V 13.142 The Q - point from problem 13.35 is (1.01 mA, 7.41 V ). ( ) ( ) id ≤ 0.4I D = 0.404mA | vd ≤ 0.4I D RD R3 = 0.404mA 7.5kΩ 220kΩ = 2.93 V 13-40 13.143 VCE = 20 − 20000IC : Two points on the load line (0mA, 20V ) , (1mA, 0V ) At IB = 2µA, the maximum swing is approximately 2.5 V limited by VRC . For IB = 5µA,the maximum swing is approximately - 8.5 V limited by VCE . IC I B= 10 µA 1000 µA I = 8 µA B 750 µA I = 6 µA B 500 µA I B = 5 µA I = 4 µA B 250 µA 8.5 V 9V I = 2 µA B V 0 CE 0 10 V 2.5 V 20 V 13-41 CHAPTER 14 14.1 (a) Common-collector Amplifier (npn) (emitter-follower) RI Q1 R vi R 1 2 + R R E 3 vo - (b) Not a useful circuit because the signal is injected into the drain of the transistor. M 1 RI + vi R3 RD R1 vo - (c) Common-emitter Amplifier (pnp) R 1 R 2 RI Q 1 1kΩ vi RC R + 3 vo 100 k Ω - © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-1 14.1 (d) Common-source Amplifier (NMOS) + RI M 1k Ω R vi 1 R 1 R 3 RD vo 470 k Ω - 2 (e) Common-gate Amplifier (PMOS) RI R vi + M1 RD 1 R3 vo - (f) Common-collector Amplifier (emitter-follower) (npn) RI Q vi R 1 1 + R 2 RE R3 v o - 14-2 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.1(h) Common-base Amplifier (pnp) + R3 RC v Q1 o - R I v RE i (i) Not a useful circuit since the signal is being taken out of the base terminal. Q1 + vo - RB R3 RI vi RE (j) Common-source Amplifier (PMOS) RI M1 1k Ω vi R 1 R 2 + RD R3 470 k Ω v o - © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-3 14.1(k) Common-gate Amplifier (Depletion-mode NMOS) M1 RI vi + R RS vo 3 - RD (l) Not a useful circuit because the signal is injected into the drain of the transistor. M RI 1 + R3 vi RD vo RS - (n) Common-emitter Amplifier (npn) + RI R3 Q1 vo R vi B (o) Common-drain Amplifier (Source-follower) (NMOS) RI M vi R G + R3 vo - 14-4 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.2 V DD RS CC1 RI 1k Ω vi CC2 CB + RG RL RD -V SS vo 100 k Ω 14.3 VDD RS RI vi CC2 CC1 RL 1k Ω RG + vo 100 k Ω CB RD -V SS 14.4 V DD RS RI CC1 1k Ω CB CC2 vi + RG RL RD -V SS vo 100 k Ω © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-5 14.5 +15 V 15 kΩ RC CC2 RI + RL CC1 v Q1 150 kΩ 3.3 k Ω O - RB vI 220 kΩ CB RE 22 kΩ -15 V 14.6 +15 V 15 kΩ RC +15 V RI RI CB CC1 CC1 Q1 Q1 3.3 k Ω vI 3.3 k Ω RB RB CC2 220 kΩ RE RL 22 kΩ (a) 150 kΩ vI + CC2 220 kΩ RE - 22 kΩ (b) -15 V + RL vO vO - 150 kΩ -15 V 14.7 +15 V +15 V 15 kΩ RC 15 kΩ RC CC2 CC2 vO CB Q1 150 kΩ RB 220 kΩ CC1 (a) 14-6 - 150 kΩ CC1 RI -15 V vI 22 kΩ (b) RI 3.3 kΩ RE vI 22 kΩ vO Q1 3.3 kΩ RE + RL + RL -15 V © R. C. Jaeger & T. N. Blalock - February 20, 2007 - 14.8 (a) Neglecting R out Av = Avt : Avt = − (0.005S )(2000Ω) = −3.77 g m RL =− 1+ g m RS 1+ (0.005S )(330Ω) ⎛ ⎞ RG 2 MΩ = -3.77⎜ ⎟ = -3.64 RI + RG ⎝ 75kΩ + 2 MΩ ⎠ [ Rin = RG = 2 MΩ | ] Rout = ro (1+ g m RS ) = 10kΩ 1+ (0.005S )(330Ω) = 26.5 kΩ >> 2kΩ Ai = −RG (b) A v gm 0.005S = −2 MΩ = −3770 1+ g m RS 1+ (0.005S )(330Ω) ⎛ RG ⎞ ⎛ ⎞ 2 MΩ = −g m RL ro ⎜ ⎟ = −(0.005S ) 2kΩ 10kΩ ⎜ ⎟ = −8.03 ⎝ 75kΩ + 2 MΩ ⎠ ⎝ RI + RG ⎠ ( ) ( ) Rin = RG = 2 MΩ | Rout = ro = 10.0 kΩ | Ai = −RG g m = −2 MΩ(0.005S ) = −10000 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-7 14.9 (a) g m 75 = 3750Ω .02 rπ + (β o + 1)RE = 15kΩ 3750Ω + 76(300Ω) = 9.58 kΩ = 0.02S | rπ = Rin = RB [ ] [ ] ⎛ Rin ⎞ ⎛ Rin ⎞ β o RL Neglecting Rout : Av = Avt ⎜ ⎟=− ⎜ ⎟ rπ + (β o + 1)RE ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ Av = − Rout 75(12kΩ) ⎛ ⎞ 9.58kΩ ⎜ ⎟ = −32.2 3750Ω + 76(300Ω)⎝ 500Ω + 9.58 kΩ ⎠ ⎡ ⎤ ⎛ ⎞ 75(300Ω) β o RE ⎢ ⎥ = 596 kΩ >> 12kΩ ≅ ro ⎜1+ ⎟ = 100kΩ 1+ ⎢ ⎥ 15kΩ 500Ω + 3750Ω + 300Ω ⎝ Rth + rπ + RE ⎠ ⎣ ⎦ ( ) Ai = −β o RB 15kΩ = −75 = −27.1 RB + rπ + (β o + 1)RE 15kΩ + 3750Ω + 76(300Ω) (b) g 75 = 3750Ω .02 rπ + (β o + 1)RE = 15kΩ 3750Ω + 76(620Ω) = 11.6 kΩ m = 0.02S | rπ = Rin = RB [ ] [ ] ⎛ Rin ⎞ ⎛ Rin ⎞ β o RL Neglecting Rout : Av = Avt ⎜ ⎟=− ⎜ ⎟ rπ + (β o + 1)RE ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ Av = − 75(12kΩ) ⎛ ⎞ 11.6kΩ ⎜ ⎟ = −17.0 3750Ω + 76(620Ω)⎝ 500Ω + 11.6kΩ ⎠ ⎤ ⎡ ⎛ ⎞ 75(620Ω) β o RE ⎥ = 1060 kΩ >> 12kΩ ⎢ = 100kΩ 1+ Rout ≅ ro ⎜1+ ⎟ ⎥ ⎢ ⎝ Rth + rπ + RE ⎠ 15kΩ 500Ω + 3750Ω + 620Ω ⎦ ⎣ ( Ai = −β o ) RB 15kΩ = −75 = −17.1 15kΩ + 3750Ω + 76(620Ω) RB + rπ + (β o + 1)RE 14.10 (a ) For large β o : Av ≅ − 8.2kΩ 47kΩ RL =− = −6.91 | RE 330Ω + 680Ω parallel with the 330Ω resistor. Then Av ≅ − (b) Place a bypass capacitor in 8.2kΩ 47kΩ RL =− = −10.3 | RE 680Ω bypass capacitor in parallel with the 680Ω resistor. Then Av ≅ − (c) Place a 8.2kΩ 47kΩ = −21.2 330Ω (d) Place a bypass capacitor from the emitter to ground. (e) Av ≅ −10(VCC + VEE )= −240. 14-8 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.11 Rin = rπ + (β o + 1)RE = 250 kΩ Avt = − 75RL β o RL =− = −10 → RL = 33.3 kΩ → 33 kΩ 250kΩ rπ + (β o + 1)RE Assuming (β o + 1)RE >> rπ , RE ≅ 250 kΩ 250 kΩ = = 3.29 kΩ → 3.3 kΩ 76 βo + 1 As indicated above, the nearest 5% values would be 33 kΩ and 3.3 kΩ. 14.12 Rin = rπ = 250 kΩ | rπ = βo gm = β oVT IC | IC = β oVT rπ = 75(0.025V ) 250kΩ = 7.50 µA ⎞ ⎛ r 75RL β R Av = −g m RL ⎜ π ⎟ = − o L = − = −10 | RL = 33.3 kΩ → 33 kΩ Rth + rπ 100Ω + 250kΩ ⎝ Rth + rπ ⎠ The closest 5% value is RL = 33 kΩ. 14.13 ⎡ix − gm v gs⎤ ⎡ go −go ⎤⎡v d ⎤ ⎢ ⎥=⎢ ⎥⎢ ⎥ | v gs = −v s ⎣ +gm v gs ⎦ ⎣−go go + GS ⎦⎣ v s ⎦ ⎡ix ⎤ ⎡ go −(gm + go ) ⎤⎡v d ⎤ ⎥⎢ ⎥ ⎢ ⎥=⎢ ⎣0 ⎦ ⎣−go gm + go + GS ⎦⎣ v s ⎦ vd gm vgs + vgs R th r o - R ix 5 ix (gm + go + GS ) = ix ∆ go G S ⎛ g ⎛ v G ⎞ r ⎞ = d = RS ⎜1+ m + S ⎟ = RS ⎜1+ µ f + o ⎟ ix RS ⎠ ⎝ go go ⎠ ⎝ ∆ = goGS | v d = (gm + go + GS ) Rout Rout = ro + (1+ µ f )RS ≅ ro + µ f RS = ro (1+ gm RS ) © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-9 14.14 (15 − 0.7 )V = 1.29 µA | I C = 129 µA | VCE = 30 − 39000 I C − 100000 I E 1MΩ + (100 + 1)100kΩ 100(0.025V ) Active region is correct. | r = = 19.4kΩ | r - no V specified - neglect IB = π 129 µA o = 11.9 V A RL = 500kΩ 39kΩ = 36.2kΩ | Rin = RB rπ = 1MΩ 19.4kΩ = 19.0kΩ ⎛ Rin ⎞ 19.0kΩ ⎞ ⎟⎟ = 40(0.129mA)(36.2kΩ )⎛⎜ Av = − g m RL ⎜⎜ ⎟ = −182 ⎝ 500Ω + 19.0kΩ ⎠ ⎝ RI + Rin ⎠ Rout = RC ro = 39 kΩ ⎛ Rin ⎞ 19.0kΩ 0.005V ⎛ ⎞ ⎟⎟ = vi ⎜ vbe = vi ⎜⎜ vi ≤ = 5.13 mV ⎟ = 0.974vi R R 500 Ω + 19 . 0 k Ω 0 . 974 + ⎝ ⎠ I in ⎠ ⎝ Av ≅ −10(VCC + VEE ) = −10(30 ) = −300. | A closer estimate is - 40VR C = -40(5.03) = −201 14.15 62kΩ = 6.80V | REQ = 20kΩ 62kΩ = 15.1kΩ 20kΩ + 62kΩ (9 − 0.7 − 6.80)V = 4.82µA | I = 361 µA | V = 9 − 3900I − 8200I = 4.61 V IB = C EC E C 15.1kΩ + (75 + 1)3.9kΩ VEQ = 9 Active region is correct. | rπ = 75(0.025V ) 361µA = 5.19kΩ | VA not specified, choose ro = ∞ Rin = 15.1kΩ 5.19kΩ = 3.86 kΩ | Rout = ro 8.2kΩ = 8.2 kΩ | g m = 40IC = 12.6 mS RL = ro 8.2kΩ 100kΩ = 8.2kΩ 100kΩ = 7.58kΩ ⎛ Rin ⎞ ⎛ 3.86kΩ ⎞ Av = −g m RL ⎜ ⎟ = −(12.6mS )(7.58kΩ)⎜ ⎟ = −75.9 ⎝1kΩ + 3.86kΩ ⎠ ⎝ RI + Rin ⎠ Rout 8.2kΩ RB 15.1kΩ −β o ) = −75) = −4.23 Ai = ( ( RB + rπ Rout + R3 15.1kΩ + 5.19kΩ 8.2kΩ + 100kΩ vbe = vi Rin 3.86kΩ 5.00mV = vi = 0.794v i | vi = = 6.30 mV 1kΩ + 3.86kΩ 0.794 RI + Rin Av ≅ −10VCC = −10(9)= −90. | The voltage gain is slightly below the rule - of - thumb estimate. 14-10 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.16 VEQ = 15 500kΩ = 3.95V | REQ = 500kΩ 1.4 MΩ = 368kΩ 1.4 MΩ + 500kΩ 2I D + 27000I D → I D = 79.7µA 250x10−6 = 15 − I D (75kΩ + 27kΩ) = 6.87 V | Active region operation is correct. 3.95 = VGS + 27000I D = 1+ VDS ( )( ) g m = 2 250x10−6 79.7x10−6 = 0.200mS | Assume λ = 0, ro = ∞. RL = ro 75kΩ 470kΩ ≅75kΩ 470kΩ = 64.7kΩ Rin = RG = R1 R2 = 368 kΩ | Rout = ro 75kΩ ≅ 75kΩ Av = −g m RL ⎛ 368kΩ ⎞ Rin = −(0.200mS )(64.7kΩ)⎜ ⎟ = −12.9 RI + Rin ⎝ 1kΩ + 368kΩ ⎠ Ai = RG (−g m ) vgs = vi RD 75kΩ = 368kΩ(−0.200mS ) = −10.1 RD + R3 75kΩ + 470kΩ Rin 368kΩ = vi = 0.997v i | VGS − VTN = RI + Rin 1kΩ + 368kΩ vgs ≤ 0.2(VGS − VTN )→ vi ≤ 0.2 2(79.7µA) 250µA/V 2 = 0.798V 0.798V VDD 15 = 0.160 V | Av ≅ − =− = −18.8 0.997 0.798 VGS − VTN VDD . We have VR L = 79.7µA(75kΩ)= 5.98V = 0.399VDD 2 The estimate also doesn't account for the presence of R3 . The rule - of - thumb estimate assumes VR L = © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-11 14.17 2.2 MΩ = 11.0V | RG = REQ = 2.2 MΩ 2.2 MΩ = 1.10 MΩ 2.2 MΩ + 2.2 MΩ Assume active region operation. VEQ = 22 22 = 22000I D − VGS + 11 | 11 = 22000I D + 1+ [ ] 2(400x10 )(391x10 ) = 0.559mS 2I D → I D = 391 µA 400x10−6 VDS = − 22 − I D (22kΩ + 18kΩ) = −6.36 V | Active region operation is correct. gm = −6 −6 | Assume λ = 0, ro = ∞ RL = ro 18kΩ 470kΩ ≅18kΩ 470kΩ = 17.3kΩ | Rin = 1.10 MΩ | Rout = ro 18kΩ = 18kΩ ⎛ Rin ⎞ 1.1MΩ Av = −g m RL ⎜ = −9.48 ⎟ = −(0.559mS )(17.3kΩ) 22kΩ + 1.1MΩ ⎝ RI + Rin ⎠ RD 18kΩ Ai = −g m Rin = −0.559mS (1.1MΩ) = −22.7 RD + R3 18kΩ + 470kΩ Rin 1.1MΩ = vi = 0.980vi | VGS − VTN = RI + Rin 22kΩ + 1.1MΩ ⎛1.40V ⎞ vgs ≤ 0.2(VGS − VTN ) | vi ≤ 0.2⎜ ⎟ = 0.286 V ⎝ 0.980 ⎠ vgs = vi 2(391µA) 400µA/V 2 14.18 2 2 Kn 4x10−4 V = −5) = 5.00 mA ( ( TN ) 2 2 = 16 −1800I D = 7.00V | Active region operation is correct. VGS = 0 → I D = VDS ( )( ) g m = 2 4x10 4 5x10−3 = 2.00mS | Assume λ = 0, ro = ∞. ⎛ RG ⎞ ⎛ 10 MΩ ⎞ Av = -g m RL ⎜ ⎟ = −(2.00mS ) 1.8kΩ 36kΩ ⎜ ⎟ = −3.43 ⎝ 10 MΩ + 5kΩ ⎠ ⎝ RI + RG ⎠ ( ) Rin = 10.0 MΩ | Rout = RD ro = 1.80 kΩ ⎛ RD ⎞ ⎛ ⎞ 1.8kΩ Ai = −g m RG ⎜ ⎟ = −2.00mS (10 MΩ)⎜ ⎟ = −952 ⎝ 1.8kΩ + 36kΩ ⎠ ⎝ RD + R3 ⎠ ⎛ 10 MΩ ⎞ vgs = vi ⎜ ⎟ ≤ 0.2VGS − VTN → vi ≤ 1 V ⎝10 MΩ + 5kΩ ⎠ 14-12 © R. C. Jaeger & T. N. Blalock - February 20, 2007 = 1.40V 14.19 (12 − 0.7)V = 14.9µA | I = 1.19 mA | V = 24 − 9100I = 13.2 V 20kΩ + (80 + 1)9.1kΩ 80(0.025V ) (100 + 13.2)V = 95.1kΩ Active region is correct. | r = = 1.68kΩ | r = IB = C CE π E o 1.19mA 1.19mA RL = ro 1MΩ = 95.1kΩ 1MΩ = 86.9kΩ | Rin = RB rπ = 20kΩ 1.68kΩ = 1.55 kΩ | Rout = ro = 95.1 kΩ ⎛ Rin ⎞ 1.55kΩ = −3560 Av = -g m RL ⎜ ⎟ = −40(1.19mA)(86.9kΩ) 250Ω + 1.55kΩ ⎝ RI + Rin ⎠ ⎛ RB ⎞⎛ ro ⎞ ⎛ ⎞⎛ ⎞ 20kΩ 95.1kΩ Ai = −β o ⎜ ⎟⎜ ⎟ = −80⎜ ⎟⎜ ⎟ = −6.41 ⎝ 20kΩ + 1.68kΩ ⎠⎝ 95.1kΩ + 1MΩ ⎠ ⎝ RB + rπ ⎠⎝ ro + R3 ⎠ ⎛ Rin ⎞ 1.55kΩ 5.00mV = 0.861v i | vi ≤ = 5.81 mV vbe = vi ⎜ ⎟ = vi 250Ω + 1.55kΩ 0.861 ⎝ RI + Rin ⎠ 14.20 80 = 200Ω | Assume VA = ∞, ro = ∞. 0.4S Rin = RB rπ + (β o + 1)RL = 47kΩ 200Ω + 81(1kΩ) = 29.8 kΩ rπ = [ Rout = Av = + ] ( ) [ ] 47kΩ 10kΩ + 200Ω Rth + rπ = = 104 Ω βo + 1 81 (β + 1)R + (β + 1)R o rπ L o ⎛ Rin ⎞ ⎛ ⎞ 81(1kΩ) 29.8kΩ ⎟= ⎜ ⎜ ⎟ = 0.747 200Ω + 81(1kΩ)⎝10kΩ + 29.8kΩ ⎠ L ⎝ RI + Rin ⎠ ⎡ ⎤⎛ r ⎞ 47kΩ RB ⎢ ⎥⎜ o ⎟ = 81 = 29.7 Ai = +(β o + 1) 47kΩ + 200Ω + 81(1kΩ) ⎢⎣ RB + rπ + (β o + 1)RL ⎥⎦⎝ ro + RL ⎠ 14.21 Assume λ = 0, ro = ∞. | Rin = RG = 2 MΩ | Rout = Av = + 1 = 100 Ω gm ⎞ 0.01(2kΩ) ⎛ g m RL ⎛ Rin ⎞ 2 MΩ ⎜ ⎟= ⎜ ⎟ = 0.907 1+ g m RL ⎝ RI + Rin ⎠ 1+ 0.01(2kΩ)⎝100kΩ + 2 MΩ ⎠ ⎛ r ⎞ Ai = +g m RG ⎜ o ⎟ = 0.01(2 MΩ)= 2x10 4 ⎝ ro + RL ⎠ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-13 14.22 Defining v1 as the source node: (a) 2kΩ 100kΩ = 1.96kΩ (v − v ) + 3.54x10 v − v = v ( ) 1960 10 1 i −3 6 −3 1 MΩ 1 1 i + −3 3.541x10 vi = 4.051x10 v1 v1 = 0.874v i | Av = 0.874 Rin = + vi v RG g v gs m gs - - v vi v = −6 i = 7.94 MΩ ii 10 (vi − v1 ) 1 2kΩ 100 k Ω Driving the output with current source ix : Rout : ix = Rout = v1 v + 1 + 3.54x10−3 v1 6 10 2000 (b) R v1 = 247 Ω | ix in =∞ 14.23 100kΩ = −6.00V | REQ = 100kΩ 100kΩ = 50.0kΩ 100kΩ + 100kΩ (−0.7 + 6)V = 8.25µA | IC = 1.03 mA | VCE = 24 − 2000IC − 4700I E = 17.1 V IB = 50.0kΩ + (126)(4.7kΩ) VEQ = −12 + 12 Active region is correct. | rπ = 125(0.025V ) = 3.03kΩ | ro = (50 + 17.1)V = 65.1kΩ 1.03mA 1.03mA RB = R1 R2 = 100kΩ 100kΩ = 50.0kΩ | RL = R3 RE ro = 24kΩ 4.7kΩ 65.1kΩ = 3.71kΩ [ ] [ ] Rin = RB rπ + (β o + 1)RL = 50.0kΩ 3.03kΩ + (126)3.71kΩ = 45.2 kΩ Av = + (β + 1)R + (β + 1)R o rπ L o ⎞ ⎛ R ⎛ ⎞ 126(3.71kΩ) 50.0kΩ in ⎟= ⎜ ⎜ ⎟ = 0.984 R + R 500Ω + 50.0kΩ 3.03kΩ + 126 3.71kΩ ⎝ ⎠ ⎠ ⎝ ( ) I in L ⎞ ⎛ ⎤ ⎞⎛ ⎛ R ⎞⎡ rπ 3.03kΩ 50.0kΩ in ⎟=⎜ ⎢ ⎥ = 6.34x103 vi vbe = vi ⎜ ⎟⎜⎜ ⎟ ⎟ R + R 500Ω + 50.0kΩ r + β + 1 R 3.03kΩ + 126 3.71kΩ ⎠⎢⎣ ⎝ I ( o ) L⎠ ⎝ ( )⎥⎦ in ⎠⎝ π vi ≤ 0.005V = 0.784 V | R out = RE 6.34x10−3 14-14 (R B ) RI + rπ βo + 1 = 4.7kΩ (50.0kΩ 500Ω)+ 3.03kΩ = 27.8 Ω © R. C. Jaeger & T. N. Blalock - February 20, 2007 126 14.24 VGS = 5V | I D = 2 5x10−4 5 −1.5) = 3.06 mA | VDS = 5 − (−5)= 10V - Pinchoff region ( 2 ( ) [ ] operation is correct. | g m = 2 5x10−4 (3.06mA) 1+ 0.02(10) = 1.92mS 1 + 10 V ro = 0.02 = 19.6 kΩ − Cannot neglect! | RL = 19.6kΩ 100kΩ = 16.4kΩ 3.06 mA 1 Rin = RG = 1 MΩ | Rout = ro = 507 Ω gm ⎛ 1.92mS (16.4kΩ) ⎞ Rin ⎛ g m RL ⎞ 1MΩ ⎟ = 0.960 ⎜ Av = + = + ⎜ ⎟ RI + Rin ⎝ 1+ g m RL ⎠ 10kΩ + 1MΩ ⎜⎝1+ 1.92mS (16.4kΩ)⎟⎠ ⎤ ⎛ ⎞⎡ ⎛ Rin ⎞⎛ 106 Ω 1 1 ⎞ ⎥ = 0.0305v i ⎢ v gs = v i ⎜ ⎟ ⎟⎜ ⎟ = vi⎜ 4 6 ⎝ RI + Rin ⎠⎝ 1+ g m RL ⎠ ⎝ 10 Ω + 10 Ω ⎠⎢⎣1+ 1.92mS (16.4kΩ)⎥⎦ vi ≤ VDS 0.2(5 −1.5) = 23.0 V But, vDS must exceed vGS − VTN ≅ VGS − VTN = 4V for pinchoff. 0.0305 = 10 − vo = 10 − 0.970vi ≥ 4 → vi ≤ 6.19 V − Limited by the Q - point voltages 14.25 (9 − 0.7)V = 187 nA | I = 18.7 µA | V 1MΩ + (100 + 1)430kΩ 100(0.025V ) = 134kΩ | Active region is correct. | r = IB = C π CE 18.7µA = 18 − 430000I E = 9.89 V ro = (60 + 9.89)V = 3.74 MΩ - neglected 18.7µA In the ac model, R1 appears in parallel with rπ . The circuit appears to be using a transistor with rπ' = 500kΩ rπ = 106kΩ and β o' = g mrπ' = 40(18.7µA)106kΩ = 79.0 ( ) RL = 500kΩ 430kΩ 500kΩ = 158kΩ | Rin = rπ' + β o' + 1 RL = 106kΩ + 79.0(158kΩ)= 12.6 MΩ (β + 1)R ⎛⎜ R A = r + (β + 1)R ⎝ R + R ' o v ' π Rout ' o in L I ⎞ ⎛ ⎞ 80.0(158kΩ) 12.6 MΩ ⎟= ⎜ ⎟ = +0.992 106kΩ + 80.0(158kΩ)⎝ 500Ω + 12.6 MΩ ⎠ in ⎠ RI + rπ' 500Ω + 106kΩ = RE R2 ' = 430kΩ 500kΩ = 1.34 kΩ 79.0 βo + 1 vbe = vi vi ≤ L rπ' ( ) RI + rπ + β + 1 RL ' ' o = vi 106kΩ = 8.32x10−3 vi 500Ω + 106kΩ + 80.0(158kΩ) 0.005V = 0.601 V 8.32x10−3 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-15 14.26 vi ≤ 0.005(1+ g m RL ) | RL = RE R3 ≅ RE ⎛ I R ⎞ vi ≤ 0.005(1+ g m RL ) = 0.005(1+ g m RE ) = 0.005⎜1+ C E ⎟ VT ⎠ ⎝ ⎛ ⎛ I R ⎞ I R ⎞ vi ≤ 0.005⎜1+ α F E E ⎟ ≅ 0.005⎜1+ E E ⎟ VT ⎠ VT ⎠ ⎝ ⎝ ⎛ VR ⎞ ⎛ VR E ⎞ vi ≤ 0.005⎜1+ E ⎟ = 0.005⎜1+ ⎟ = 0.005 + 0.2VR E VT ⎠ ⎝ ⎝ 0.025 ⎠ 14.27 β o = g mrπ = 3.54mS (1MΩ) = 3540 | RL = 2kΩ 100kΩ = 1.96kΩ (β + 1)R r + (β + 1)R = r + (β + 1)R Av = Rin o L π o L π o L Rout = 2kΩ (3540 + 1)(1.96kΩ) = 0.874 1MΩ + (3540 + 1)(1.96kΩ) = 1MΩ + (3540 + 1)(1.96kΩ)= 7.94 MΩ = rπ 106 = 2kΩ = 247 Ω (β o + 1) (3541) 14.28 (a) v be (b) A v = v i − vo | 0.005 ≤ 5 − v o → Av = = (β + 1)R + (β + 1)R o rπ E o E = vo 4.995 ≥ = 0.999 5 vi 1 1 1 1 = = = βo rπ αo rπ V 1+ 1+ 1+ 1+ T g m RE I E RE (β o + 1)RE (β o + 1) βo RE V 0.025V 1 ≥ 0.999 → T ≤ 0.001 → I E RE ≥ = 25.0 V VT 0.001 I E RE 1+ I E RE 14-16 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.29 vbe = vi − vo = (1− Av )vi | 0.005 ≤ (1− Av )7.5 → Av = vo 7.5 − 0.005 ≥ = 0.999333 vi 7.5 1 500RE 1 | RL = RE 500Ω = | Av = ⎛ V 500 + RE 500 + RE ⎞ V 1+ T 1+ T ⎜ ⎟ I E RL I E RE ⎝ 500 ⎠ 1 V ⎛ 500 + RE ⎞ −4 ≥ 0.999333 → T ⎜ ⎟ ≤ 6.67x10 ⎛ ⎞ I R 500 500 + RE V ⎠ E E ⎝ 1+ T ⎜ ⎟ I E RE ⎝ 500 ⎠ From Prob. 14.28, Av = 500I E RE 0.025V ≥ = 37.5V | VCC ≥ I E RE + 0.7 + 7.5 500 + RE 6.67x10−4 Some design possibilities are listed in the table below. RE IE VCC VCC IE 100 Ω 450 mA 53 V 24 W 250 Ω 225 mA 64 V 16 W 360 Ω 179mA 73V 13 W 500 Ω 150 mA 83 V 12 W 750 Ω 125 mA 102 V 13 W 1000 Ω 113mA 120 V 14 W 2000 Ω 93.8 mA 196 V 18 W Using a result near the minimum-power case in the table: RE = 510 Ω  E= 149 mA and VCC = 85 V. 149mA = 2.92 mA | Set I R1 = 5I B = 14.6mA ≅ 15mA For β F = 50 : I B ≅ 51 V + VBE 149mA(510Ω)+ 0.7 R1 = E = = 5.07kΩ → 5.1 kΩ | I R 2 = I R1 + I B ≅ 18mA I R1 15mA 85 − VBE − VBE 8.3V = = 462Ω → 470 Ω I R2 18mA It is obviously very difficult to achieve the required level of linearity! R2 = © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-17 14.30 (a) g m = 40(12.5µA)= 0.5mS Rin = R4 Av = rπ α 0.99 = R4 o = 100kΩ = 1.94 kΩ βo + 1 gm 0.5mS ⎛ R4 ⎞ ⎛ 100kΩ ⎞ 0.5mS (100kΩ) ⎜ ⎟= ⎜ ⎟ = 48.7 1+ g m RI R4 ⎝ RI + R4 ⎠ 1+ 0.5mS 50Ω 100kΩ ⎝ 50Ω + 100kΩ ⎠ g m RL ( [ ) ( )] ) 60V 1+ 0.5mS (50Ω) = 4.92 MΩ 12.5µA ⎛ R4 ⎞ ⎛ 100kΩ ⎞ Ai = α o ⎜ ⎟ = 0.990⎜ ⎟ = 0.990 ⎝ 50Ω + 100kΩ ⎠ ⎝ RI + R4 ⎠ ( [ Rout = ro 1 + g m RI R4 = (b) A = v ] 0.5mS (100kΩ) ⎛ ⎞ 100kΩ ⎜ ⎟ = 23.6 | Rin = 1.94kΩ - no change 1+ 0.5mS 2.2kΩ 100kΩ ⎝ 2.2kΩ + 100kΩ ⎠ ( [ Rout = ro 1 + g m ) 60V (R R )]= 12.5 [1+ 0.5mS (2.2Ω)]= 10.1 MΩ µA 4 I 14.31 (a) R in Av = 1 1 = 3kΩ = 1.20 kΩ | Rout = ∞ (assume λ = 0) gm 0.5mS = R4 ⎛ R ⎞ 0.5mS (60kΩ) ⎛ 3kΩ ⎞ 4 ⎜ ⎟= ⎜ ⎟ = +28.8 1+ g m RI R4 ⎝ RI + R4 ⎠ 1+ 0.5mS 50Ω 3kΩ ⎝ 50Ω + 3kΩ ⎠ g m RL ( Ai = 1 (b) A v R4 R4 + = 1 gm ) = ( ) 3kΩ = 0.600 3kΩ + 2kΩ 0.5mS (60kΩ) ⎛ 3kΩ ⎞ 1 = 1.43 kΩ ⎜ ⎟ = +5.81 | Rin = 5kΩ 0.5mS 1+ 0.5mS 5kΩ 3kΩ ⎝ 5kΩ + 3kΩ ⎠ Rout = ∞ | Ai = ( ) 5kΩ = 0.714 5kΩ + 2kΩ 14.32 The voltage gain is approximately 0. The signal is injected into the collector and taken out of the emitter. This is not a useful amplifier circuit. 14-18 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.33 IB = (12 − 0.7)V = 2.64µA | 100kΩ + (50 + 1)82kΩ IC = 132 µA VCE = 24 − 82000I E − 39000IC = 7.81 V | Active region operation is correct. g m = 40IC = 5.28mS | rπ = βo gm = 9.47kΩ | ro = (50 + 7.81)V = 438kΩ - neglected 132µA RI RE = 0.5kΩ 82kΩ = 497Ω | RL = RC R3 = 39kΩ 100kΩ = 28.1kΩ Av = ⎛ RE ⎞ 5.28mS (28.1kΩ) ⎛ ⎞ 82kΩ ⎜ ⎟= ⎜ ⎟ = 40.7 1+ g m RI RE ⎝ RI + RE ⎠ 1+ 5.28mS (497Ω)⎝ 500Ω + 82kΩ ⎠ g m RL ( Rin = 82kΩ ) rπ 500Ω + 185Ω R + Rin = 185 Ω | Ai = Av I = 40.7 = 0.279 100kΩ βo + 1 R3 Rout = RC = 39.0 kΩ | veb = vi Rin ≤ 5.00mV | 0.270vi ≤ 5.00mV | vi ≤ 18.5 mV RI + Rin 14.34 IB = (9 − 0.7)V = 194nA | 1000kΩ + (50 + 1)820kΩ IC = 9.69 µA VCE = 18 − 820000I E − 390000IC = 6.12 V | Active region is correct. g m = 40IC = 0.388mS | rπ = βo gm = 129kΩ | ro = (50 + 6.12)V = 5.79 MΩ - neglected 9.69µA RI RE = 5kΩ 820kΩ = 4.97kΩ | RL = RC R3 = 390kΩ 1MΩ = 281kΩ Av = ⎛ RE ⎞ 0.388mS (281kΩ) ⎛ 820kΩ ⎞ ⎜ ⎟= ⎜ ⎟ = 37.0 1+ g m RI RE ⎝ RI + RE ⎠ 1+ 0.388mS (4.97kΩ)⎝ 5kΩ + 820kΩ ⎠ g m RL ( Rin = 820kΩ ) rπ 5kΩ + 2.52kΩ R + Rin = 2.52 kΩ | Ai = Av I = 37.0 = 0.278 1MΩ βo + 1 R3 Rout ≅ RC = 390 kΩ | veb = vi Rin ≤ 5.00mV | 0.335vi ≤ 5.00mV | vi ≤ 14.9 mV RI + Rin © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-19 14.35 (5x10 )(V = −3900 −4 VGS = −3900I D (5x10 )(V 2 −4 ID = gm = 2 2(254µA) 2 − 0.992 + 2) | VGS = −0.975(VGS + 2) → VGS = −0.9915V 2 GS 2 + 2) = 254µA | VDS = 16 − 23.9kΩI D = 9.92V - Pinched off. 2 GS = 0.504mS | Rin = 3.9kΩ 1 = 1.32kΩ | Rout ≅ RD = 20kΩ gm RL = 20kΩ 51kΩ = 14.4kΩ Av = ⎛ RS ⎞ 0.504mS (14.4kΩ) ⎛ 3.9kΩ ⎞ ⎜ ⎟= ⎟ = 4.12 ⎜ 1+ g m RI RS ⎝ RI + RS ⎠ 1+ 0.504mS (0.796kΩ)⎝1kΩ + 3.9kΩ ⎠ g m RL ( ) Ai = Av 1kΩ + 1.32kΩ RI + Rin = 4.12 = 0.187 51kΩ R3 vgs = vi 1.32kΩ 1.32kΩ ≤ 0.2(VGS + 2) | v i ≤ 0.2(−0.992 + 2)→ vi ≤ 0.354 V 1kΩ + 1.32kΩ 1kΩ + 1.32kΩ 14.36 (2x10 )(V = −4 ID GS + 1) | 2 2 15 + VGS = 10−4 (VGS + 1) → VGS = −2.363V 68kΩ 2 15 + VGS = 186µA | VDS = − 30 − (68kΩ + 43kΩ)I D = −9.35V | ID = 68kΩ 2(186µA) 1 = 0.274mS | Rin = 68kΩ = 3.46kΩ Pinchoff region is correct. | g m = 2.36 −1 gm [ ] Rout ≅ RD = 43kΩ | RL = 43kΩ 200kΩ = 35.4kΩ Rin 3.46kΩ g m RL = (0.274mS )(35.4kΩ)= 9.05 RI + Rin 0.250kΩ + 3.46kΩ ⎛ 3.71kΩ ⎞ R + Rin 3.46kΩ Ai = Av I = 9.05⎜ ≤ 0.2(VSG −1) ⎟ = 0.168 | vgs = vi R3 0.250kΩ + 3.46kΩ ⎝ 200kΩ ⎠ 3.46kΩ vi ≤ 0.2(2.36 −1)→ v i ≤ 0.292 V 0.250kΩ + 3.46kΩ Av = 14-20 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.37 VGS = −10 + (33kΩ)I D | VGS (3.3x10 )(2x10 )(V = −10 + 4 (2x10 )(V −4 VGS = −2.507 V & I D = VDS GS −4 2 GS + 1) 2 + 1) = 227µA 2 2 = − 20 − I D (33kΩ + 24kΩ) = −7.06 V - Active region operation is correct. [ ] 2(2x10 )(2.27x10 ) = 3.01x10 −4 gm = −4 −4 S | RI RS = 0.5kΩ 33kΩ = 493Ω Assume λ = 0, ro = ∞ | RL = RD R3 = 24kΩ 100kΩ = 19.4kΩ Av = ⎛ RS ⎞ 0.301mS (19.4kΩ) ⎛ ⎞ 33kΩ ⎜ ⎟= ⎜ ⎟ = 5.01 1+ g m RI RS ⎝ RI + RS ⎠ 1+ 0.301mS (493Ω)⎝ 500Ω + 33kΩ ⎠ g m RL ( Ai = 1 ) ⎛ RD ⎞ ⎛ ⎞ 33kΩ 24kΩ ⎜ ⎟= ⎜ ⎟ = 0.176 1 ⎝ RD + R3 ⎠ 33kΩ + 3.32kΩ ⎝ 24kΩ + 100kΩ ⎠ RS + gm Rin = RS vgs = vi RS 1 = 3.02 kΩ | Rout = RD = 24kΩ gm RIN 3.02kΩ ≤ 0.2VGS + 1 | vi ≤ 0.2(1.51)→ vi ≤ 0.352 V 0.5kΩ + 3.02kΩ RI + RIN 14.38 For Rth << 1 , Av ≅ g m RL All of the input voltage appears across the gate - source gm terminals of the transistor. 1 R For Rth >> , Av ≅ L For large Rth , all of the Thevenin equivalent source Rth gm current, 14.39 Rin = vth , goes into the transistor source terminal. Rth 75(0.025V ) rπ + 1.5kΩ 1.88kΩ + 1.5kΩ | rπ = = 1.88kΩ | Rin = = 44.5 Ω βo + 1 1mA 76 14.40 g m = 2(1.25mA)(1mA) = 1.58mS | Rin = 1 = 633 Ω gm © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-21 14.41 ⎡ 15V − 0.7V β o RE ⎤ a R = r 1+ ⎢ ( ) out o⎣ r + R ⎥⎦ | I E = 143kΩ = 100µA | For β F = 100, IC = 99.0µA π E rπ = Rout 100(0.025V ) = 25.3kΩ | ro ≅ 50V = 505kΩ 99.0µA 99.0µA ⎡ 100(143kΩ) ⎤ ⎥ = 43.4 MΩ ⎢ = 505kΩ 1+ ⎢⎣ 25.3kΩ + 143kΩ⎥⎦ (b) 0 V 100(0.025V ) 15V − 0.7V = 953µA | For β F = 100, IC = 944µA | rπ = = 2.65kΩ 15kΩ 944µA ⎡ 100(15kΩ) ⎤ 50V ⎥ = 4.56 MΩ | VCB ≥ 0 V ro ≅ = 53.0kΩ | Rout = 53.0kΩ ⎢1+ 944µA ⎢⎣ 15kΩ + 2.65kΩ⎥⎦ (c) I E = 14.42 ⎛V + V ⎞ ⎛ 50 + 10.7 ⎞ Rout = (β o + 1)ro = (β o + 1) ⎜ A CE ⎟ = 126 ⎜ ⎟ = 154 MΩ ⎝ 49.6µA ⎠ ⎝ IC ⎠ 14.43 43 Rin = 350Ω | Av = 10 20 = 141 | Low Rin , large gain A common - base amplifier can achieve these speocfications. 1 1 → IC ≅ = 71.4 µA gm 40(350) Rin ≅ A common emitter amplifier operating at a higher current is an alternate choice. 100 Rin ≅ rπ → IC ≅ = 7.14 mA 40(350) For both cases, Av ≅ 10VCC → VCC = 14 V 14.44 Rin = 0.3 MΩ | Av = 10 46 20 = 200 | Fairly large Rin , large gain A common - emitter amplifier operating at a low current can achieve both a large gain and input resistance. Av ≅ 20VCC → VCC = 10V Achieving this gain with an FET is much more difficult : Av ≅ VDD V = DD → VDD ≅ 50V which is unreasonably large. VGS −V TN 0.25V 14-22 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.45 26 Rin = 10 MΩ | Av = 10 20 = 20 | Large Rin , moderate gain These requirements are readily met by a common - source amplifier. VDD 15V For example, Av ≅ = = 30. VGS −V TN 0.5V A common - emitter stage operating at a low collector current with ⎛ ⎞ 10 MΩ an unbypassed emitter resistor ⎜ R E ≅ = 100kΩ⎟is a second possibility, 100 ⎝ ⎠ but the circuit will require careful design. 14.46 58 20 Rin = 50kΩ | Av = 10 = 792 | A bipolar transistor would be required for such a large gain. However, this is a large fraction of the BJT amplification factor [i. e. (40/V)(75V) = 3000] and will be very difficult to achieve with the information thus far (the active load discussed later is a possibility). Using our rule - of - thumb for the common - emitter amplifier, Av ≅ 10VCC → VCC = 80 V which is too large. Thus, it is not possible is the best answer. 14.47 An inverting amplifier with a gain of 40 dB is most easily achieved with a common - emitter stage : Av ≅ 10VCC → VCC = 10 V. The input resistance can be achieved by shunting the input with a 5 - Ω resistor. Setting rπ = 5 Ω would require IC ≅ 100(0.025V ) = 0.5A and would 5Ω waste a large amount of power to achieve the required input resistance. It would be better to operate the transistor at a much lower current and "swamp" the input resistance by shunting the input with a 5 - Ω resistor 14.48 A non - inverting amplifier with a gain of 20 and an input resistance of 5 kΩ should be readily achievable with either a common - base or common - gate amplifier with proper choice of operating point. The gain of 10 is easily achieved with either the VDD 1 FET or BJT design estimate : Av ≅ or Av ≅ 10VCC . Rin ≅ = 5 kΩ is within gm VGS − VTN easy reach of either device. The gain and input resistance can also be easily met with either a common - emitter, or common - source stage with a resistor shunt at the input. 14.49 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-23 0 - dB gain corresponds to a follower ( Av = 1). For an emitter - follower, R in ≅ (β o + 1)RL ≅ 101(20kΩ) = 2.02 MΩ. So an BJT cannot meet the input resistance requirement. A source follower provides a gain of approximately 1 and can easily achieve the required input resistance. 14.50 A gain of 0.97 and an input resistance of 400kΩ should be achievable with g m RL either a source - follower or an emitter - follower. For the FET, Av ≅ = 0.97 1+ g m RL requires g m RL = 33.3 : 2I D RL = 33.3 → I D RL = 8.3V for a design with VGS − VTN = 0.5V. VGS − VTN The BJT can achieve the required gain with a much lower power supply and can still meet the Rin requirement : Rin ≅ β o RL ≅ 100(5kΩ) = 500kΩ. Av ≅ g m RL = 0.97 | g m RL = 33.3 → IC RE = 33.3(0.025)= 0.833 V. 1+ g m RL The requirements can be met with careful bias circuit design and specification of a BJT with minimum current gain of at least 100. 14.51 66 Av = 10 20 = 2,000. This value of voltage gain approaches the amplification factor of the BJTs : Av ≤ µ f = 40VA = 40(75)= 3000. Such a large gain requirement cannot be met with single - transistor BJT amplifiers using the resistive loaded amplifiers in this chapter (Remember the 10VCC limit). FETs typically have much lower values of µf and are at an even worse disadvantage. None of the single - transistor amplifier configurations can meet the gain requirements. 14-24 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.52 Such a large output resistance will require either a CE or CB stage or a CS or CG stage. For a BJT, Rout ≤ β oro β oVA 100(75V ) = 7.5µA using typical 109 Ω values for β o and VA . We need to also see how much voltage is required. IC = 109 Ω or IC = 75 > 109 Ω → IC RE > 2.5 V whihc is reasonable. We also need ro (1+ g m RE )> 109 Ω or 40(IC RE ) 7.5µA For a MOSFET, Rout = ro (1+ g m RS ) ≅ g mro RS = RS = 109 (0.01/V )(0.25V ) 2 = 1.25 MΩ 2RS = 109 Ω λ(VGS − VTN ) For typical values, Using this value to estimate the required voltage, 2 2Kn ⎛ RS ⎞ 2(0.001)⎛1.25x106 ⎞ RS 9 = 10 Ω → I D = 18 ⎜ ⎟ = g mro RS = 2Kn I D ⎟ = 31.3µA and ⎜ λI D 10 ⎝ λ ⎠ 1018 ⎝ 0.01 ⎠ 2 VR S = 39 V which is getting large. So the BJT appears to be the best choice. 14.53 Rout = Rth + rπ βo + 1 | Assuming Rth ≅ RI and rπ = 0, Rout ≥ RI 250 = = 1.66 Ω β o + 1 151 14.54 Rin = rπ + (β o + 1)RE ≅ rπ + β o RE = rπ (1+ g m RE ) | rπ' = rπ (1+ g m RE ) g m' = ro' = ic gm βo βo βo = ≅ = = vi rπ + (β o + 1)RE rπ + β o RE rπ (1+ g m RE ) 1+ g m RE ic vc ⎛ βR ⎞ ⎛ β R ⎞ = ro⎜1+ o E ⎟ ≅ ro⎜1+ o E ⎟ = ro (1+ g m RE ) for rπ >> RE rπ ⎠ ⎝ rπ + RE ⎠ ⎝ v i =0 ⎛ ⎛ gm ⎞ gm ⎞ ' ' ' ⎟rπ (1+ g m RE ) = β o | µ f = g mro = ⎜ ⎟ro (1+ g m RE ) = µ f ⎝1+ g m RE ⎠ ⎝1+ g m RE ⎠ β o' = g m' rπ' = ⎜ 14.55 *Problem 14.55 - Common-Emitter Amplifier 5mV VCC 6 0 DC 9 VEE 4 0 DC -9 VS 1 0 SIN(0 0.005 1K) C1 1 2 1U RB 2 0 10K RC 6 5 3.6K RE 3 4 2K C2 3 0 50U C3 5 7 1U © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-25 R3 7 0 10K Q1 5 2 3 NBJT .OP .TRAN 1U 5M .FOUR 1KHZ V(7) .MODEL NBJT NPN IS=1E-16 BF=100 VA=70 .PROBE V(7) .END *Problem 14.55 - Common-Emitter Amplifier 10mV VCC 6 0 DC 9 VEE 4 0 DC -9 VS 1 0 SIN(0 0.01 1K) C1 1 2 1U RB 2 0 10K RC 6 5 3.6K RE 3 4 2K C2 3 0 50U C3 5 7 1U R3 7 0 10K Q1 5 2 3 NBJT .OP .TRAN 1U 5M .FOUR 1KHZ V(7) .MODEL NBJT NPN IS=1E-16 BF=100 VA=70 .PROBE V(7) .END *Problem 14.55 - Common-Emitter Amplifier 15mV VCC 6 0 DC 9 VEE 4 0 DC -9 VS 1 0 SIN(0 0.015 1K) C1 1 2 1U RB 2 0 10K RC 6 5 3.6K RE 3 4 2K C2 3 0 50U C3 5 7 1U R3 7 0 10K Q1 5 2 3 NBJT .OP .TRAN 1U 5M .FOUR 1KHZ V(7) .MODEL NBJT NPN IS=1E-16 BF=100 VA=70 .PROBE V(7) .END Results: 1 kHz 2 kHz 3 kHz vi 14-26 THD © R. C. Jaeger & T. N. Blalock - February 20, 2007 5 mV 5.8 mV 10 mV 15 mV 12.4 mV 20.6 mV 0.335 mV (5.7%) 0.043 mV (0.74% 1.54 mV (12.5%) 0.258 mV (2.1%) 4.32 mV (21%) 1.18 mV (5.4%) 5.9% 12.8% 22% 14.56 *Problem 14.56 - Output Resistance VCC 2 0 DC 10 IB1 0 1 DC 10U Q1 2 1 0 NBJT IB2 0 3 DC 10U RE 4 0 10K Q2 2 3 4 NBJT .OP .DC VCC 10 20 .025 .MODEL NBJT NPN IS=1E-16 BF=60 VA=20 .PRINT DC IC(Q1) IC(Q2) .PROBE IC(Q1) IC(Q2) .END Results: A small value of Early voltage has been used deliberately to accentuate the results. Note that the transistors have significantly different values of F because of the collectoremitter voltage differences and low value of VA. NAME Q1 Q2 MODEL NBJT NBJT IB 1.00E-05 1.00E-05 IC 8.77E-04 6.72E-04 VBE 7.61E-01 7.61E-01 VBC -9.24E+00 -2.41E+00 VCE 1.00E+01 3.18E+00 BETADC 8.77E+01 6.72E+01 GM 3.39E-02 2.60E-02 RPI 2.59E+03 2.59E+03 RO 3.33E+04 3.33E+04 From SPICE : Rout1 = (20 −10) V (20 −10) V = 43.5 kΩ = 34.1 kΩ | Rout 2 = (1.17 − 0.877) mA (903 − 673) µA For circuit 1: Rout1 = ro1 = 33.3 kΩ ⎛ ⎞ β o RE For circuit 2 : Rout 2 = ro2⎜1+ ⎟ + (Rth + rπ ) RE (See Eq. 14.28) ⎝ Rth + rπ + RE ⎠ But Rth = ∞ → Rout 2 = ro2 + RE = 33.3kΩ + 10kΩ = 43.3 kΩ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-27 14.57 ⎛ ⎛ 100(270Ω) ⎞ β o RI ⎞ ⎜ ⎟ = 384 kΩ Rth ≅ ro ⎜1+ ⎟ = 250kΩ⎜1+ ⎟ 270Ω + 50kΩ ⎝ RI + rπ ⎠ ⎝ ⎠ vi vth = isc Rth = RI + αo α o Rth = gm vi 0.990 270Ω + 0.002 0.990(384 kΩ) → vth = 479v i 14.58 vth = Gm Rth = − [ ] gm ro (1+ g m RS ) vi = −µ f v i = −(0.5mS )(250kΩ)vi = −125vi 1+ g m RS Rth = ro (1+ g m RS ) = ro + µ f RS = 250kΩ + 125(18kΩ)= 2.50 MΩ 14.59 (β vth = v i o + 1)ro RI + rπ + (β o + 1)ro = vi 1 rπ RI + +1 (β o + 1)ro (βo + 1)ro = vi 1 g m RI βo + +1 (β o + 1)µ f (β o + 1)µ f RI + rπ R +r RI α ro ≅ I π = + o βo + 1 βo + 1 βo + 1 gm Rth ≅ 14.60 (a) g i1 i2 g12 = (b) g 21 21 = v2 v1 v1 =0 = i2 =0 g m RE ≅1 1+ g m RE ⎛ 1 ⎞ ie ⎛ 1 ⎞ R E 1 ⎛ g m RE ⎞ 1 =⎜ = ⎟ ≅⎜ ⎟ ⎜ ⎟≅ βo + 1 ⎝1+ g m RE ⎠ βo ⎝ β o + 1⎠ i 2 ⎝ β o + 1⎠ R + 1 E gm = 0.960 | g12 = 9.51x10−3 | g21 >> g12 14.61 (a) g g12 = 21 i1 i2 = | v2 = i2 =0 ( g m RD ro ( ) 1+ g m RD ro v1 | g21 = ) ( g m RD ro ( ) 1+ g m RD ro ) ≅1 | i1 = v1 =0 (b) g21 = 14-28 v2 v1 ( ) 0.2mS 50kΩ 450kΩ ( ) 1+ 0.2mS 50kΩ 450kΩ = 0.947 | g12 = 0 | g21 >> g12 © R. C. Jaeger & T. N. Blalock - February 20, 2007 ≅ vi 14.62 (a) g i1 i2 g12 = (b) g 21 21 = v2 v1 ( ) ( | v2 = g m RC ro v1 | g21 = g m RC ro i2 =0 =− v1 =0 RC ro + RC R r r + RC g21 = gm C o o = g mro = µ f >> 1 g12 ro + RC RC | ( ) ) = 3mS 18kΩ 800kΩ = 52.8 g12 = − 18kΩ = 0.0220 18kΩ + 800kΩ i1 i2 =− 14.63 (a) g (b) g 21 21 = v2 v1 ( = +g m RD ro i2 =0 )| ( g12 = v1 =0 RD | g21 = −g mro g12 ≅ −µ f g12 RD + ro ) = +0.5mS 100kΩ 500kΩ = 41.7 | g12 = − 100kΩ = −0.167 | g21 >> g12 100kΩ + 500kΩ 14.64 (a) g i1 ≅ − (b) g 21 = v2 v1 | v2 ≅ − i2 = 0 g m RC g R v1 | g21 = − m C 1+ g m RE 1+ g m RE | g12 = i1 i2 v1 = 0 ⎛ RE ⎞ ⎛ RE ⎞ ⎛ RE ⎞ i2 RC v2 RC ⎟≅− ⎟ | g12 = − ⎟ ⎜ ⎜ ⎜ ro (1+ g m RE )⎝ RE + rπ ⎠ ro (1+ g m RE )⎝ RE + rπ ⎠ ro (1+ g m RE )⎝ RE + rπ ⎠ 21 =− 2mS (130kΩ) 1+ 2mS (12kΩ) = -10.4 | g12 = − ⎞ ⎛ 12kΩ -3 ⎟ = -1.01x10 ⎜ 1MΩ 1+ 2mS (12kΩ) ⎝12kΩ + 50kΩ ⎠ [ 130kΩ ] g21 >> g12 14.65 (a) g g12 = (b) g 21 i1 i2 = v2 v1 v1 = 0 21 = − i2 = 0 g m RD g R v1 | g21 ≅ − m D 1+ g m RS 1+ g m RS | i1 = 0 | g12 = 0 | | v2 ≅ − 0.75mS (130kΩ) 1+ 0.75mS (12kΩ) = −9.75 g12 =0 g21 | g21 >> g12 | g12 = 0 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-29 14.66 gm + go vx g o + GL ⎛ g + go ⎞ ⎛ GL − g m ⎞ i | x = g m + g o ⎜1− m ⎟ = g m + g o⎜ ⎟ vx ⎝ g o + GL ⎠ ⎝ g o + GL ⎠ At the output node v o : g mvx = (g o + GL )vo − g ovx | vo = ix = g mvx + g o (vx − v o ) ⎛G − g ⎞ ix gm + go m = g m + g o⎜ L ⎟ = GL vx g o + GL ⎝ g o + GL ⎠ RL v 1 1 ⎛ RL ⎞ ro | Rin = x = ≅ ⎜1+ ⎟ 1 ix g m ro ⎠ gm ⎝ 1+ 1+ µf 14.67 IC = 100 5 − 0.7 ( ) 10 + 101 10 4 3 = 3.87mA | g m = 40IC = 0.155S | rπ = 100 = 645Ω gm RL = 1kΩ 20kΩ = 952Ω | RE = 1kΩ 20kΩ = 952Ω Av1 = − Av2 = 100(952Ω) β o RL =− = −0.984 rπ + (β o + 1)RE 645Ω + 101(952Ω) (β + 1)R + (β + 1)R o rπ E o E = 101(952Ω) 645Ω + 101(952Ω) = 0.993 The small - signal requirement limits the output signal to : vbe = vi − vo2 = vi (1− 0.993) = 0.007vi | v i ≤ vo1 ≤ 0.984(0.714V ) = 0.703V 0.005 = 0.714V 0.007 We also need to check VCB : VC = 5 − 3.87mA(1kΩ)= 1.13V and VB = −10 4 I B = −0.387V. The total collector - base voltage of the transistor is therefore : VCB = 1.52V − 0.984v i − vi . We require VCB ≥ 0 for forward - active region operation. Therefore : vi ≤ 0.766 V. The small - signal limit is the most restrictive. 14-30 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.68 100kΩ = 0V | REQ = 100kΩ 100kΩ = 50kΩ 100kΩ + 100kΩ 0 − 0.7 − (−15) = 22.3µA | IC = 2.78 mA | I E = 2.81 mA IB = 50kΩ + 126(4.7kΩ) (a) VEQ = −15 + 30 VCE = 30 − 2000IC − 4700I E = 11.4 V rπ = 125(0.025V ) = 1.12kΩ | ro = (50 + 11.4)V = 22.1kΩ 2.78mA 2.78mA RB = R1 R2 = 100kΩ 100kΩ = 50kΩ | RL = R3 RE ro = 24kΩ 4.7kΩ 22.1kΩ = 3.34kΩ [ ] [ ] Rin = RB rπ + (β o + 1)RL = 50kΩ 1.12kΩ + (126)3.34kΩ = 44.7 kΩ Av = + (β + 1)R + (β + 1)R o rπ Rout = RE ro L o (R B ⎞ ⎛ R ⎛ ⎞ 126(3.34kΩ) 44.7kΩ in ⎟= ⎜ ⎜ ⎟ = 0.984 1.12kΩ + 126(3.34kΩ)⎝ 0.600kΩ + 44.7 kΩ ⎠ L ⎝ RI + Rin ⎠ ) RI + rπ = 4.7kΩ 22.1kΩ (44.7kΩ 600Ω)+ 1.12kΩ = 13.5 Ω 126 βo + 1 (b) SPICE Results: Q-point: (2.81 mA, 11.1 V), Av = 0.984, Rin = 45.5 kΩ Rout = 13.0 Ω 14.69 (10 − 0.7)V = 1.43 µA | I = 114 µA | V 1MΩ + (80 + 1)68kΩ 81(0.025V ) Active region is correct. | r = = 17.8 kΩ IB = C π 114µA CE = 20 − 39000IC − 68000I E = 7.71 V | ro = 75 + 7.71 = 726 kΩ 114µA RL = 500kΩ 39kΩ 726kΩ = 34.5kΩ | Rin = RB rπ = 1MΩ 17.8kΩ = 17.5 kΩ ⎛ Rin ⎞ ⎞ ⎛ 17.5kΩ Av = −g m RL ⎜ ⎟ = 40(0.114mA)(34.5kΩ)⎜ ⎟ = −153 ⎝ 500Ω + 17.5kΩ ⎠ ⎝ RI + Rin ⎠ Rout = RC ro = 39kΩ 726kΩ = 37.0 kΩ ⎛ Rin ⎞ ⎞ ⎛ 17.5kΩ vbe = vi ⎜ ⎟ = vi ⎜ ⎟ = 0.972vi ⎝ 500Ω + 17.5kΩ ⎠ ⎝ RI + Rin ⎠ vi ≤ 0.005V = 5.14 mV 0.972 Av ≅ −10(VCC + VEE ) = −10(20)= −200. | A closer estimate is - 40VR C = -40(4.47) = −178 (b) SPICE Results: Q-point: (116 µA, 7.53 V), Av = -150, Rin = 19.6 kΩ, Rout = 37.0 kΩ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-31 14.70 62kΩ = 9.07V | REQ = 62kΩ 20kΩ = 15.1kΩ 62kΩ + 20kΩ 12 − 0.7 − 9.07 IB = = 4.19µA | IC = 314 µA | I E = 319 µA 15.1kΩ + 76(6.8kΩ) (a) VEQ = 12 VEC = 12 −16000IC − 6800I E = 4.81 V 75(0.025) 60 + 4.81 = 206kΩ | rπ = = 5.97kΩ −6 314x10 314x10−6 RL = ro 16kΩ 100kΩ = 206kΩ 16kΩ 100kΩ = 12.9kΩ ro = Rin = 15.1kΩ 5.97kΩ = 4.28 kΩ | Rout = ro 16kΩ = 14.8 kΩ | g m = 40IC = 12.6 mS ⎛ Rin ⎞ ⎛ 4.28kΩ ⎞ Av = −g m RL ⎜ ⎟ = −(12.6mS )(12.9kΩ)⎜ ⎟ = −132 ⎝1kΩ + 4.28kΩ ⎠ ⎝ RI + Rin ⎠ (b) SPICE Results: Q-point: (309 µA, 4.93 V), Av = -127, Rin = 4.65 kΩ Rout = 14.9 kΩ 14.71 500kΩ = 4.73V | REQ = R1 R2 = 500kΩ 1.4 MΩ = 368kΩ 500kΩ + 1.4 MΩ Assume Active Region Operation (a) V EQ = 18 2I D + 27000I D → I D = 113 µA 5x10−4 = 18 − (27000 + 75000)I D = 6.47 V > 3.73 V - Active region is correct. 4.73 = VGS = 27000I D → 4.73 = 1+ VDS 50 + 6.47 = 500kΩ | g m = 2 500x10−6 113x10−6 1+ 0.02(6.47) = 357µS −6 113x10 RL = ro RD 470kΩ = 500kΩ 75kΩ 470kΩ = 57.3kΩ ro = ( )( )[ ] Rin = R1 R2 = 500kΩ 1.4 MΩ = 368kΩ | Rout = ro 75kΩ = 65.2 kΩ ⎛ Rin ⎞ ⎛ 368kΩ ⎞ Av = −g m RL ⎜ ⎟ = −(0.357mS )(57.3kΩ)⎜ ⎟ = −20.4 ⎝ 1kΩ + 368kΩ ⎠ ⎝ RI + Rin ⎠ (b) SPICE Results: Q-point: (115 µA, 6.30 V), Av = -20.5, Rin = 368 kΩ Rout = 65.1 kΩ 14-32 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.72 (2.5x10 )(V = −4 ID 2 10 + VGS = 1.25x10−4 (VGS + 1) → VGS = −2.358V 33kΩ + 1) | 2 GS 2 10 + VGS = 232µA | VDS = −10 + 0.232mA(24kΩ)− 2.36 = −6.79V | Pinchoff region is correct. ID = 33kΩ ( )( )[ ] g m = 2 2.5x10−4 2.32x10−4 1+ 0.02(6.79) = 0.363mS | RI RS = 0.5kΩ 33kΩ = 493Ω ro= 50 + 6.79 1 =245kΩ RL = ro RD R3 = 245kΩ 24kΩ 100kΩ = 17.9kΩ | Rin = 33kΩ = 2.69 kΩ −4 gm 2.32x10 Rout = ro RD = 21.9 kΩ Av = ⎛ RS ⎞ ⎞ 0.363mS (17.9kΩ) ⎛ 33kΩ ⎟= ⎜ ⎜ ⎟ = 5.42 1+ g m RI RS ⎝ RI + RS ⎠ 1+ 0.363mS (0.493kΩ)⎝ 500Ω + 33kΩ ⎠ g m RL ( ) (b) SPICE Results: Q-point: (234 µA, -6.67V), Av = +5.56, Rin = 2.69 kΩ, Rout= 18.1 kΩ 14.73 IC = 100 rπ = 5 − 0.7 = 12.5µA | VCE = 5 − IC (330kΩ)− (−5)= 5.87V 500kΩ + 500kΩ + (101)330kΩ 100 60 + 5.87 = 200kΩ | ro = = 5.27 MΩ | RL = 500kΩ 330kΩ 500kΩ ro = 139kΩ 40(12.5µA) 12.5x10−6 Absorb R1 into the transistor : rπ' = rπ R1 = 143kΩ | β o' = g mrπ' = 71.4 ( ) Rin = rπ' + β o' + 1 RL = 143kΩ + 71.4(139kΩ)= 10.1 MΩ (R I Rout = 330kΩ 500kΩ ro ) RB + rπ' β o' + 1 (β + 1)R A =+ (R R )+ r + (β + 1)R ' o v L ' I B π ' o L = = 1.97 kΩ 72.4(139kΩ) 1kΩ + 143kΩ + 72.4(139kΩ) = 0.986 (b) SPICE Results: Q-point: (12.7 µA, 5.78 V), Av = +0.986, Rin = 10.7 MΩ, Rout= 2.00 kΩ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-33 14.74 IB = (12 − 0.7)V = 2.69 µA | 100kΩ + (51)82kΩ Active region is correct. g m = 40(135µA) = 5.40 mS | rπ = IC = 135 µA | VCE = 24 − 39000IC − 82000I E = 7.58 V 50(0.025V ) 135µA = 9.26 kΩ | ro = 50 + 7.58 = 427 kΩ 135µA Rth = RI RE = 0.5kΩ 82kΩ = 497Ω | RL = ro (1+ g m Rth ) RC R3 = 1.57 MΩ 39k Ω 100kΩ = 27.6 kΩ Av = ⎛ RE ⎞ 5.40mS (27.6kΩ) ⎛ ⎞ 82kΩ ⎟= ⎜ ⎜ ⎟ = 40.2 1+ g m RI RE ⎝ RI + RE ⎠ 1+ 5.40mS (497Ω)⎝ 500Ω + 82kΩ ⎠ g m RL Rin = 82kΩ ( ) rπ = 181 Ω | Rout = ro (1+ g m Rth ) RC = 38.1 kΩ βo + 1 (b) SPICE Results: Q-point: (132 µA, 7.79V), Av = 39.0, Rin = 204 Ω Rout = 38.0 kΩ 14.75 2.2 MΩ = 9.00V | REQ = R1 R2 = 2.2mΩ 2.2 MΩ = 1.10 MΩ 2.2 MΩ + 2.2 MΩ Assume Active Region Operation VEQ = 18 2I D + 110000I D → I D = 67.5 µA 4x10−4 = 18 − (110000 + 90000)I D = 4.50 V > 0.575 V - Active region is correct. 18 - 9 = 110000I D − VGS → 9 = 1+ VDS 50 + 4.50 = 807kΩ | g m = 2 400x10−6 67.5x10−6 1+ 0.02(4.50) = 243µS −6 67.5x10 RL = ro RD 470kΩ = 807kΩ 90kΩ 470kΩ = 69.7kΩ ro = ( )( )[ ] Rin = R1 R2 = 2.2 MΩ 2.2 MΩ = 1.1 MΩ | Rout = ro 90kΩ = 81.0 kΩ ⎛ Rin ⎞ ⎛ 1.1MΩ ⎞ Av = −g m RL ⎜ ⎟ = −(0.243mS )(69.7kΩ)⎜ ⎟ = −16.9 ⎝ 1kΩ + 1.1MΩ ⎠ ⎝ RI + Rin ⎠ (b) SPICE Results: Q-point: (66.7 µA, 4.47V), Av = -16.8, Rin = 1.10 MΩ Rout = 81.0 kΩ 14-34 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.76 5x10−4 (a ) Assume Active Region operation. V = −51000I I = 2 (V + 2) → I V = 15 − (20000 + 51000)I = 12.7 V > 0.36 V - Active Region is correct. GS DS D D ( Rout D = 32.2 µA D )( )[ ] g m = 2 5x10−4 32.2x10−6 1+ 0.02(12.70) = 0.201mS | Rin = 51kΩ ro = 2 GS 1 = 4.53kΩ gm 50 + 12.7 = 1.95MΩ | Rth = RI RS = 981Ω 32.2x10−6 = ro (1+ g m Rth ) RD = 19.8 kΩ | RL = Rout 10kΩ = 6.65kΩ Av = ⎛ R ⎞ 0.201mS (6.65kΩ) ⎛ 51kΩ ⎞ S ⎟= ⎜ ⎜ ⎟ = 1.10 1+ g m RI RS ⎝ RI + RS ⎠ 1+ 0.201mS (0.981kΩ)⎝1kΩ + 51kΩ ⎠ g m RL ( ) (b) SPICE Results: Q-point: (32.9 µA, 12.7 V), Av = +1.10, Rin = 4.50 kΩ, Rout= 19.8 kΩ 14.77 The power supply should be +16 V. (a ) Assume Active Region operation. Since there is no negative feedback (RS = 0), we should include the effect of channel - length modulation. VGS = 0 2 4x10−4 −5) (1+ 0.02VDS ) and VDS = 16 −1800I D → I D = 5.59 mA ( 2 = 16 −1800I D = 5.93 V > 5 V - Active region is correct. ID = VDS 50 + 5.93 = 10.0kΩ 5.59x10−3 ⎛ RG ⎞ ⎛ 10 MΩ ⎞ Av = -g m RL ⎜ ⎟ = −(2.24mS ) 10.0kΩ 1.8kΩ 36kΩ ⎜ ⎟ = −3.27 ⎝ 10 MΩ + 5kΩ ⎠ ⎝ RI + RG ⎠ ( ) [ ] g m = 2 4x10−4 (5.59mA) 1+ 0.02(5.93) = 2.24mS | ro = ( ) Rin = 10.0 MΩ | Rout = RD ro = 1.52 kΩ (b) SPICE Results: Q-point: (5.59 mA, -5.93V), Av = -3.27, Rin = 10.0 MΩ, Rout= 1.52 kΩ 14.78 (10 − 0.7)V = 14.0µA | I = 1.12 mA | V = 20 − 7800I = 11.3 V 33kΩ + (80 + 1)7.8kΩ 80(0.025V ) (100 + 11.3)V = 99.4kΩ = 1.79kΩ | r = Active region is correct. | r = IB = C π CE E o 1.12mA 1.12mA RL = ro 1MΩ = 95.1kΩ 1MΩ = 86.8kΩ | Rin = RB rπ = 33kΩ 1.79kΩ = 1.70 kΩ | Rout = ro = 99.4 kΩ ⎛ Rin ⎞ 1.70kΩ = −3390 Av = -g m RL ⎜ ⎟ = −40(1.12mA)(86.8kΩ) 250Ω + 1.70kΩ ⎝ RI + Rin ⎠ (b) Results: Q-point: (1.12 mA, 11.2 V), Av = -3440, Rin = 1.93 kΩ Rout= 98.9 kΩ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-35 14.79 Bias forces Active Region operation : VDS = 6 − (−6)= 12 V VGS = 6 V 2 2 Kn 4x10−4 ID = VGS − VTN ) (1+ λVDS ) = 6 −1) 1+ 0.02(12) = 6.20 mA ( ( 2 2 [ ( )( )[ ] ] g m = 2 4x10−4 6.2x10−3 1+ 0.02(12) = 2.48 mS 1 + 12 V 0.02 = 10.0kΩ − Cannot neglect! | RL = 10.0kΩ 100kΩ = 9.09kΩ ro = 6.20 mA 1 Rin = RG = 2 MΩ | Rout = ro = 388 Ω gm ⎛ 2.48mS (9.09kΩ) ⎞ 2 MΩ Rin ⎛ g m RL ⎞ ⎟ = 0.953 ⎜ Av = + ⎟=+ ⎜ 10kΩ + 2 MΩ ⎜⎝1+ 2.48mS (9.09kΩ)⎟⎠ RI + Rin ⎝ 1+ g m RL ⎠ (b) SPICE Results: Q-point: (6.20 mA, 12.0V), Av = 0.953, Rin = 2.00 MΩ, Rout= 388 Ω 14.80 (a) V EQ = 15 500kΩ = 3.95 V | REQ = 500kΩ 1.4 MΩ = 368 kΩ 1.4 MΩ + 500kΩ 2I D + 27000I D → I D = 85.1 µA 400x10−6 = 15 − I D (75kΩ + 27kΩ) = 6.32V | Active region operation is correct. Assume active region | 3.95 = VGS + 27000I D = 1+ VDS ( )( ) g m = 2 400x10−6 85.1x10−6 = 0.261 mS | ro = C1 ≥ 10 50 + 6.32 = 662 kΩ | RG = R1 R2 = 368 kΩ 85.1µA 1 10 = | C1 ≥ 0.0108 µF → 0.01 µF 2πf (RI + RG ) 2π (400Hz)(1kΩ + 368kΩ) 1 10 = | C2 ≥ 1.19 µF →1.2 µF ⎛ ⎛ ⎞ ⎞ 1 1 2πf ⎜ RS ⎟ ⎟ 2π (400Hz)⎜27kΩ 0.261mS ⎠ gm ⎠ ⎝ ⎝ 1 10 C3 ≥ 10 = | C3 ≥ 7.40 nF → 8200 pF 2π (400Hz)(67.4kΩ + 470kΩ) 2πf RD ro + R3 C2 ≥ 10 [( ) ] (b) C 2 14-36 = 1 ⎛ 1⎞ 2πf ⎜ RS ⎟ gm ⎠ ⎝ = 1 ⎛ ⎞ 1 2π (4000Hz)⎜27kΩ ⎟ 0.261mS ⎠ ⎝ = 0.0119 µF → 0.012 µF © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.81 62kΩ = 9.07V | REQ = 20kΩ 62kΩ = 15.1kΩ 20kΩ + 62kΩ (12 − 0.7 − 9.07)V = 7.16µA | I = 537 µA | V = 12 − 3900I − 8200I = 5.47 V IB = C EC E C 15.1kΩ + (75 + 1)3.9kΩ (a) V EQ = 12 Active region is correct. rπ = 75(0.025V ) 537µA = 3.49kΩ | ro = 60 + 5.47 = 122kΩ | g m = 40IC = 21.5 mS 537µA Rin = R1 R2 rπ = 15.1kΩ 3.49kΩ = 2.83 kΩ | Rout = ro RC = 122kΩ 8.2kΩ = 7.68 kΩ C1 ≥ 10 1 10 = | C1 ≥ 4.16 µF → 0.01 µF 2πf (RI + Rin ) 2π (100Hz)(1kΩ + 2.83kΩ) 1 10 | C2 ≥ 273 µF → 270 µF ⎛R R +r ⎞ ⎛1kΩ 15.1kΩ + 3.49kΩ ⎞ I EQ π ⎟ 2π (100Hz)⎜ ⎟ 2πf ⎜⎜ ⎟ ⎟ ⎜ β + 1 76 o ⎠ ⎠ ⎝ ⎝ 1 10 = | C3 ≥ 0.148 µF → 0.15 µF C3 ≥ 10 2πf [Rout + R3 ] 2π (100Hz)(7.68kΩ + 100kΩ) C2 ≥ 10 (b) C 2 = = 1 ⎛R R +r ⎞ I EQ π ⎟ 2πf ⎜⎜ ⎟ ⎝ βo + 1 ⎠ = 1 ⎛ 1kΩ 15.1kΩ + 3.49kΩ ⎞ ⎟ 2π (1000Hz)⎜⎜ ⎟ 76 ⎝ ⎠ = 2.73 µF → 2.7 µF 14.82 IC = 100 5 − 0.7 ( ) 10 4 + 101 103 = 3.87mA | g m = 40IC = 0.155S | rπ = 100 = 645Ω | ro = ∞ gm The capacitors will be negligible at a frequency 10 times the individual break frequencies : [ ( )] Req1 = 10kΩ rπ + (β o + 1) 1kΩ 20kΩ = 9.06kΩ | f1 = 10 = 87.8 Hz 2π (9.06kΩ)2µF ⎡ rπ ⎤ 10 ⎥ = 20.0kΩ | f2 = = 7.96 Hz Req2 = 20kΩ + ⎢1kΩ 2π (20.0kΩ)10µF ⎢⎣ (β o + 1)⎥⎦ Req3 = Rout + 20kΩ = 21.0kΩ | f 3 = 10 = 7.56 Hz 2π (21.0kΩ)10µF © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-37 14.83 80 ⎛ 5 − 0.7 ⎞ 80 = 319µA | g m = 40IC = 12.8mS | rπ = = 6.26kΩ | ro = ∞ ⎜ 3⎟ 81 ⎝ 13.3x10 ⎠ gm ⎡ 10 rπ ⎤ ⎥ = 152Ω | C1 = = 0.209 µF → 0.20 µF Req1 = 75Ω + ⎢13.3kΩ 2π (50kHz)152Ω ⎢⎣ (β o + 1)⎥⎦ (a) I C = αF IE = Req2 = Rout + 100kΩ = 8.25kΩ + 100kΩ = 108kΩ | C2 = ⎛ 50kHz ⎞ (b) C = 0.209µF⎜⎝100Hz ⎟⎠ = 105 µF →100 µF 1 10 = 295 pF → 270 pF 2π (50kHz)108kΩ ⎛ 50kHz ⎞ | C2 = 295 pF ⎜ ⎟ = 0.148 µF → 0.15 µF ⎝ 100Hz ⎠ 14.84 51kΩ = −4.87V | REQ = 51kΩ 100kΩ = 33.8kΩ 51kΩ + 100kΩ −4.87 − 0.7 − (−15) V = 18.5µA | IC = 1.85 mA Assume active region operation | I B = 33.8kΩ + (101)(4.7kΩ) VEQ = −15 + 15 [ ] VCE = 30 − 4700I E = 21.2 V | g m = 40(1.85mA)= 7.40mS Active region is correct. | rπ = 100(0.025V ) = 1.35kΩ | ro = (50 + 21.2)V = 38.5kΩ 1.85mA 1.85mA RB = R1 R2 = 51kΩ 100kΩ = 33.8kΩ | RL = R3 RE ro = 24kΩ 4.7kΩ 38.5kΩ = 3.57kΩ [ (R =R ] [ ] Rin = RB rπ + (β o + 1)RL = 33.8kΩ 1.35kΩ + (101)3.57kΩ = 30.9 kΩ Rout B E ) RI + rπ βo + 1 = 4.7kΩ (33.8kΩ 500Ω)+ 1.35kΩ = 18.2 Ω 101 C1 = 10 10 = = 1.01µF →1.0 µF 2πf (RI + Rin ) 2π (50Hz)(500Ω + 30.9kΩ) C2 = 10 10 = = 1.33µF →1.5 µF 2πf (R3 + Rout ) 2π (50Hz)(24kΩ + 18.2Ω) 14-38 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.85 Note : RS ≡ R1 = 3.9kΩ | Assume active region operation. (5x10 )(V = −3900 −4 VGS = −3900I D (5x10 )(V −4 ID = 2 2(254µA) gm = 2 − 0.992 [ GS GS 2 + 2) | VGS = −0.975(VGS + 2) → VGS = −0.9915V 2 2 + 2) = 254µA | VDS = 15 − 23.9kΩI D = 8.92V - Active region is correct. 2 = 0.504mS | ro = ( Rout = RD ro 1+ g m RS RI 50 + 8.92 1 = 232kΩ | Rin = 3.9kΩ = 1.32kΩ −6 gm 254x10 )]= 20kΩ 232kΩ[1+ 0.504mS (3.9kΩ 1kΩ)]= 18.8kΩ C1 = 10 10 = = 1.72µF → 1.8 µF 2πf (RI + Rin ) 2π (400Hz)(1kΩ + 1.32kΩ) C2 = 10 10 = = 0.0335µF → 0.033 µF 2πf (R3 + Rout ) 2π (400Hz)(100kΩ + 18.8kΩ) 14.86 (a) Use C2 to set the lower cutoff frequency to 1 kHz. C1 and C3 remain negligible at 1 kHz. C2 = 0.056 µF, C1 = 1800 pF, C3 = 0.015 µF (b) SPICE Results: fL = 925 Hz 14.87 (a ) Use C3 to set the lower cutoff frequency to 2 kHz. C1 remains negligible at 2 kHz. C1 = 8200 pF, C3 = 820 pF (b) Use C to set the lower cutoff frequency to 1 kHz. C 1 2 and C3 remain negligible at 1 kHz. C1 = 0.042 µF, C2 = 1800 pF, C3 = 0.015 µF (c) SPICE Results: For (a) fL = 1.96 kHz. For (b) fL = 1.02 kHz 14.88 Av = g m RL 2I D ≥ 0.95 → g m RL ≥ 19 | g m = 2Kn I D | VGS − VTN = = 0.5V 1+ g m RL Kn (0.5) (0.03) = 3.75mA = 2 ID 2 | RL ≥ 19 2(0.03)(0.00375) = 1.27kΩ RL = RS 3kΩ → RS ≥ 2.19kΩ | VSS = VGS + (3.75mA)RS | Possible designs : 2.4kΩ, 11.5V ; 2.7kΩ, 12.6V ; 3.0kΩ, 13.75V - Making a choice which uses a nearly minimum value of supply voltage gives : VSS = 12 V , RS = 2.4 kΩ. © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-39 14.89 For a common - emitter amplifier with RE = 0, Rin ≅ rπ = β oVT IC | IC = 100(0.025V ) 75Ω = 33.3 mA 14.90 Using Eqn. 14.73 : 50 = 50 = g m RL RE 4.3V → RE = 8.65kΩ | IC ≅ = 497µA RE 1+ 40(4.3) 2(50) Rin g R | Assuming RI = 50Ω, 50 = m L → RL = = 5.03kΩ RI + Rin 2 40(497µA) RL = RC 100kΩ → RC = 5.30kΩ | VEC = 5 + 0.7 − IC RC = 3.07V - Active region is ok. C1 >> C2 >> 1 2π (500kHz)(50Ω + 50Ω) = 3.18nF → C1 = 0.033 µF 1 = 3.02 pF → C2 = 33 pF 2π (500kHz)(105kΩ) 14.91 The base voltage should remain half way between the positive and negative power supply voltages. If VEE = +10V and VCC = 0V, then VB should = 5 V which can be obtained using a resistive voltage divider from the +10V supply. We now have the standard four-resistor bias circuit. The base current is 327 µA/80 = 4.08 µA. C1 C2 + 75 Ω v 13 k Ω 8.2 k Ω RE RC 100 k Ω S 120 k Ω + 10 V R1 110 k Ω CB v O - R2 Setting the current in R1 to 10I B = 40µA, R1 = 5V = 125kΩ →120kΩ. 40µA 5V = 114kΩ →110kΩ. 44µA Note that the base terminal must now be bypassed with a capacitor. The current in R2 = 11I B = 44µA, and R 2 = 14-40 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.92 Using Eqn. 14.73 : 75 = 50 = g m RL RE 8.3V → RE = 25.0kΩ | IC ≅ = 332µA RE 1+ 40(8.3) 2(50) Rin g R | 50 = m L → RL = = 7.52kΩ | RL = RC 100kΩ → RC = 8.13kΩ RI + Rin 2 40(332µA) VEC = 9 + 0.7 − IC RC = 6.98V - Active region is ok. 1 C1 >> 2π (500kHz)(75Ω + 75Ω) C2 >> = 2.12nF → C2 = 0.022 µF 1 = 2.95 pF → C2 = 30 pF 2π (500kHz)(108kΩ) 14.93 Rin ≅ (b) I 1 0.01 → g m = 2Kn I D = 0.1S | I D = | gm 2Kn D = (a) I D = 0.01 =1 A 2(0.005) 0.01 = 10.0 mA | The second FET achieves the desired input resistance 2(0.5) at much lower current and hence much lower power for a given supply voltage. 14.94 1 VT kT = = ∝T g m IC qIC At − 40 o C = 233K, ⎛ 233k ⎞ ⎛ 323K ⎞ 1 1 o = 50Ω⎜ = 50Ω⎜ ⎟ = 38.8 Ω. | At + 50 C = 323K, ⎟ = 53.8 Ω. gm gm ⎝ 300K ⎠ ⎝ 300K ⎠ Another approach : At 27 o C = 300K, IC = At − 40 o C = 233K, 300k 6k = . 50q q 1 233 1 323 = = 38.8 Ω. | At + 50 o C = 323K, = = 53.8 Ω. gm 6 gm 6 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-41 14.95 This analysis assumes that the source and load resistors are fixed, and that only ⎛ Rin ⎞ the amplifier parameters are changing. Av = g m RL ⎜ ⎟ ⎝ RI + Rin ⎠ 1 g R 1 ≅ | Av ≅ m L Since RE >> 75Ω, RE RI ≅ 75Ω and Rin ≅ RE 1+ g m RI gm gm To achieve Avmax , RL → RLmax , g m → g mmax which requires (5.25 − 0.7)V = 364µA 13kΩ(0.95) IC → ICmax = 0.988 g m = 40(364µA) = 14.6mS | Avmax = | RLmax = 8.2kΩ(1.05)100kΩ = 7.93kΩ 14.6mS (7.93kΩ) 1+ 0.0146(75) = 55.3 min min To achieve A min which requires v , R L → RL , g m → g m IC → ICmin = 0.988 (4.75 − 0.7)V = 293µA 13kΩ(1.05) g m = 40(293µA) = 11.7mS | Avmin = | RLmin = 8.2kΩ(0.95)100kΩ = 7.23kΩ 11.7mS (7.23kΩ) 1+ 0.0117(75) = 45.1 | 45.1 ≤ Av ≤ 55.3 The range is only slightly larger than that observed in the Monte Carlo analysis in Table 14.15. 14.96 *Problem 14.96 - Common-Base Amplifier - Monte Carlo Analysis *Generate Voltage Sources with 5% Tolerances IEE 0 8 DC 5 REE 8 0 RTOL 1 EEE 6 0 8 0 1 * ICC 0 9 DC 5 RCC 9 0 RTOL 1 ECC 7 0 9 0 -1 * VS 1 0 AC 1 RS 1 2 75 C1 2 3 47U RE 3 6 RTOL 13K Q1 4 0 3 PBJT RC 4 7 RTOL 8.2K C2 4 5 4.7U R3 5 0 100K .OP .AC LIN 1 10KHZ 10KHZ .PRINT AC VM(5) VP(5) .MODEL PBJT PNP (BF=80 DEV 25%) (VA = 60 DEV 33.33%) 14-42 © R. C. Jaeger & T. N. Blalock - February 20, 2007 .MODEL RTOL RES (R=1 DEV 5%) .MC 1000 AC VM(5) YMAX .END Results: Mean value Av = 47.5; 3σ limits: 42.5 ≤ Av ≤ 52.5. However, the worst-case values observed in the analysis are Avmin = 43.2 and Avmax = 51.9. The mean is 5% lower than the design value. The width of the distribution is approximately the same as that in Table 14.15. 14.97 (a ) This analysis assumes that the source and load resistors are fixed, and that only the amplifier parameters are changing. Av = Rth = RE RI and RE = RI + RE Since R E >> RI , Rth and g m RL ⎛ RE ⎞ ⎜ ⎟ 1+ g m Rth ⎝ RI + RE ⎠ 1 where RE = 13.3kΩ and RI = 75Ω RI 1+ RE RE are essentially constant. To achieve Avmax , RL → RLmax , g m → g mmax RI + RE which requires IC → ICmax = 0.988 (5.10 − 0.7)V = 330µA | R = 8.25kΩ 1.01 100kΩ = 7.69kΩ ( ) 13.3kΩ(0.99) 13.2mS (7.69kΩ)⎡ 13.3(0.99) ⎤ ⎢ ⎥ = 50.7 = 1+ 0.0132(75) ⎢⎣ 75 + 13.3(0.99)⎥⎦ max L g m = 40(330µA) = 13.2mS | Avmax To achieve Avmin , RL → RLmin , g m → g mmin which requires IC → ICmin = 0.988 (4.90 − 0.7)V = 309µA 13.3kΩ(1.01) | RLmin = 8.25kΩ(0.99)100kΩ = 7.55kΩ 12.4mS (7.55kΩ)⎡ 13.3(1.01) ⎤ ⎢ ⎥ = 48.2 1+ 0.0124(75) ⎢⎣ 75 + 13.3(1.01)⎥⎦ (b) Using a Spreadsheet similar to Table 14.16: Mean value Av = 49.6; 3σ limits: 48.2 ≤ Av ≤ 50.9. The worst-case values observed in the analysis are Avmin = 48.4 and Avmax = 50.8. g m = 40(309µA) = 12.4mS | Avmax = 14.98 *Problem 14.98 - Common-Base Amplifier - Monte Carlo Analysis *Generate Voltage Sources with 2% Tolerances IEE 0 8 DC 5 REE 8 0 RTOL 1 EEE 6 0 8 0 1 * ICC 0 9 DC 5 RCC 9 0 RTOL 1 ECC 7 0 9 0 -1 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-43 * VS 1 0 AC 1 RS 1 2 75 C1 2 3 100U RE 3 6 RR 13.3K Q1 4 0 3 PBJT RC 4 7 RR 8.25K C2 4 5 1U R3 5 0 100K .OP .AC LIN 1 10KHZ 10KHZ .PRINT AC VM(5) VP(5) IM(VS) IP(VS) .MODEL PBJT PNP (BF=80 DEV 25%) (VA = 60 DEV 33.33%) .MODEL RTOL RES (R=1 DEV 2%) .MODEL RR RES (R=1 DEV 1%) .MC 1000 AC VM(5) YMAX *.MC 1000 AC IM(VS) YMAX .END Results: Mean value: Av = 47.2; 3σ limits: 45.7 ≤ Av ≤ 48.5 Mean value: Rin = 83.4 Ω; 3σ limits: 79.5 Ω ≤ Av ≤ 87.6 Ω 14.99 Rin = RE 1 RE RE = = = g m 1+ g m RE 1+ 40IC RE I E RE = 2.5 − 0.7 = 1.8V | 75 = RE RE = 80 1+ 39.5I E RE 1+ 40 I E RE 81 RE → RE = 5.41kΩ 1+ 39.5(1.8) 80 1.8V = 329µA | Rth = 75Ω 5.41kΩ = 74.0Ω | g m = 40(329µA)= 13.2mS 81 5.41kΩ g m RL ⎛ RE ⎞ Av = ⎟ → RL = 7.59kΩ ⎜ 1+ g m Rth ⎝ RI + RE ⎠ IC = 7.59kΩ = RC 100kΩ → RC = 8.21kΩ | VC = −2.5V + IC RC = +0.201V | Oops! We are violating our definition of the forward - active region. If we use the nearest 5% values, RE = 5.6kΩ and RC = 8.2kΩ, IC = 318µA and VC = +0.108V. The transistor is just entering saturation. 14-44 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.100 Using a Spreadsheet similar to Table 14.15: Mean value: Av = 0.960; 3σ limits: 0.942 ≤ Av ≤ 0.979 Mean value: ID = 4.91 mA; 3σ limits: 4.27 mA ≤ ID ≤ 5.55 mA Mean value: VDS = 7.03 V; 3σ limits: 4.52 V ≤ VDS ≤ 9.54 V *Problem 14.102 - Common-Drain Amplifier - Fig. 14.34 *Generate Voltage Sources with 5% Tolerances IDD 0 7 DC 5 RDD 7 0 RTOL 1 EDD 5 0 7 0 1 * ISS 0 8 DC 20 RSS 8 0 RTOL 1 ESS 6 0 8 0 -1 * VGG 1 0 DC 0 AC 1 C1 1 2 4.7U RG 2 0 RTOL 22MEG RS 3 6 RTOL 3.6K C2 3 4 68U R3 4 0 3K M1 5 2 3 3 NMOSFET .OP .AC LIN 1 10KHZ 10KHZ .DC VGG 0 0 1 .MODEL NMOSFET NMOS (VTO=1.5 DEV 33.33%) (KP=20M DEV 50%) LAMBDA=0.02 .MODEL RTOL RES (R=1 DEV 5%) .PRINT AC VM(4) VP(4) IM(VGG) IP(VGG) .MC 1000 DC ID(M1) YMAX *.MC 1000 DC VDS(M1) YMAX *.MC 1000 AC IM(VGG) YMAX *.MC 1000 AC VM(4) YMAX .END Results: Mean value: ID = 4.97 mA; 3σ limits: 4.32 mA ≤ ID ≤ 5.62 mA Mean value: VDS = 7.19 V; 3σ limits: 6.18 V ≤ VDS ≤ 8.20 V Mean value: Rin = 22.0 MΩ; 3σ limits: 20.3 Ω ≤ Rin ≤ 24.0 Ω Mean value: Av = 0.956; 3σ limits: 0.936 ≤ Av ≤ 0.976 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-45 14.101 ac equivalent circuit Rin3 Q Rin2 R RIN Q RI M1 R 1 MΩ vi G RS1 R B2 D1 620 Ω 17.2 k Ω 200 Ω OUT 2 R C2 R 10 k Ω 3 R B3 R 4.7 k Ω RE2 E3 )( 3.3 k Ω 4.7 k Ω ) ( ) RL1 = 620Ω 17.2kΩ rπ 2 + (β o2 + 1)1.6kΩ = 598Ω 2.39kΩ + (151)1.6kΩ = 597Ω Avt1 = − 0.01(597) g m1 RL1 =− = −1.99 | RL2 = 3.54kΩ (Eq. 15.7) 1+ g m1 RS 1 1+ (0.01)200 Avt 2 = − 150(3.54kΩ) β o2 RL2 =− = −2.18 rπ 2 + (β o2 + 1)1.6kΩ 2.39kΩ + (151)1.6kΩ ⎛ ⎞ 1MΩ Avt 3 = +0.950 | Av = −⎜ ⎟(1.99)(−2.18)(0.950)= +4.08 ⎝ 10kΩ + 1MΩ ⎠ ⎛R +r ⎞ ⎛ ⎞ β o2 RE 2 Rout = (3300Ω) ⎜ th3 π 3 ⎟ | Rth3 = RI 3 Ro2 =RI 3 ro2 ⎜1+ ⎟ ≅ RI 3 = 4.31kΩ ⎝ β o3 + 1 ⎠ ⎝ Rth2 + rπ 2 + RE 2 ⎠ ⎛ 4.31+ 1.00 ⎞ kΩ⎟ = 64.3Ω Rout = (3.30kΩ) ⎜ 81 ⎝ ⎠ 14-46 L 51.8 k Ω The Q - points and small - signal parameter values have already been found in the text. ⎛ ⎞ Rin The bypass capacitors do not affect Rin : Rin = RG = 1 MΩ | Av = ⎜ ⎟ Avt1 Avt 2 Avt 3 ⎝ 10kΩ + Rin ⎠ ( R © R. C. Jaeger & T. N. Blalock - February 20, 2007 250 Ω 14.102 M1 : ID = 0.01 2 (VGS + 2) | VGS = −9000ID → VGS = −1.80V 2 0.01 2 (−1.8 + 2) = 200 µA | VDS = 15 − (15kΩ + 9kΩ)ID = 10.2 V 2 (50 + 10.2)V = 301kΩ gm = 2(10mA /V 2 )(0.2mA) = 2mS | ro = 0.2mA ID = 43kΩ = 3.18V | REQ 2 = 160kΩ 43kΩ = 33.9kΩ 43kΩ + 160kΩ ⎞ ⎛ 3.18 - 0.7 151 =1.35 mA | VCE 2 = 15 − ⎜ 4.7kΩ + 1.6kΩ⎟IC = 6.49 V IC 2 = 150 ⎠ ⎝ 33.9kΩ +151(1.6kΩ) 150 Q2 : VEQ 2 = 15 gm 2 = 40(1.35mA) = 54.0mS | rπ 2 = 150 (80 + 6.49)V = 64.1kΩ = 2.78kΩ | ro2 = 1.35mA 54.0mS 120kΩ = 8.53V | REQ 3 = 120kΩ 91kΩ = 51.8kΩ 120kΩ + 91kΩ ⎞ ⎛ 81 8.53 - 0.7 = 2.72 mA | VCE 3 = 15 − ⎜ 2.2kΩ⎟IC = 8.93 V IC 3 = 80 ⎠ ⎝ 80 51.8kΩ + 81(2.2kΩ) Q3 : VEQ 3 = 15 gm 3 = 40(2.72mA) = 109mS | ro3 = (60 + 8.93)V 2.72mA ⎛ ⎞ RG Av = ⎜ ⎟ Avt1 Avt 2 Avt 3 ⎝10kΩ + RG ⎠ ( = 25.3kΩ | rπ 3 = 80 = 734Ω 109mS ) Avt1 = −(2mS ) 301kΩ 15kΩ 33.9kΩ 2.78kΩ = −4.36 ⎡ ⎤ Avt 2 = (−54.0mS )⎢64.1kΩ 4.7kΩ 51.8kΩ 734 + 81(2.2kΩ 250Ω) ⎥ = −180 ⎣ ⎦ ( Avt 3 = ) 81(2.2kΩ 250Ω) ⎛ ⎞ 1MΩ = 0.961 | Av = −4.36(−180)(0.961)⎜ ⎟ = 747 ⎝10kΩ + 1MΩ ⎠ 734 + 81(2.2kΩ 250Ω) v be 3 = v b 3 (1− Avt 3 ) = 0.99Avt1 Avt 2v s (1− Avt 3 ) ≤ 5mV | v s ≤ 0.005 = 165µV 0.99(4.36)(180)(1− 0.961) The gain is actually reduced rather than improved. The signal range increased since the gain was reduced. © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-47 14.103 *Problem 14.102/14.103 - Multistage Amplifier – Figure P14.102 VCC 12 0 DC 15 VI 1 0 AC 1 *For output resistance *VI 1 0 AC 0 *VO 11 0 AC 1 RS 1 2 10K C1 2 3 22U RG 3 0 1MEG M1 5 3 4 4 NMOSFET RS1 4 0 9K C2 4 0 22U RD 12 5 15K C3 5 6 22U R1 12 6 160K R2 6 0 43K Q2 8 6 7 NBJT1 RC 12 8 4.7K RE2 7 0 1.6K C4 7 0 22U C5 8 9 22U R3 12 9 91K R4 9 0 120K Q3 12 9 10 NBJT2 RE3 10 0 2.2K C6 10 11 22U RL 11 0 250 .MODEL NMOSFET NMOS VTO=-2 KP=.01 LAMBDA=0.02 .MODEL NBJT1 NPN IS=1E-16 BF=150 VA=80 .MODEL NBJT2 NPN IS=1E-16 BF=80 VA=60 .OPTIONS TNOM=17.2 .OP .AC LIN 1 2KHZ 2KHZ .PRINT AC VM(3) VP(3) IM(VI) IP(VI) VM(11) VP(11) IM(C6) IP(C6) .END VM(3) 1 Results : Av = VM(11) = +879 | Rin = = 1.00 MΩ | Rout = = 51.8 Ω IM(VI) IM(C6) 14-48 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.104 ⎛ ⎞ Rin The bypass capacitors do not affect Rin : Rin = RG = 1 MΩ | Av = ⎜ ⎟ Avt1 Avt 2 Avt 3 ⎝ 10kΩ + Rin ⎠ RL1 = (15kΩ 160kΩ 43kΩ) (rπ 2 + (β o2 + 1)1.6kΩ) = 10.4kΩ [2.78kΩ + 151(1.6kΩ)] = 9.98kΩ Avt1 = − 2(9.98kΩ) gm1RL1 =− = −1.05 1+ gm1 RS1 1+ 2(9kΩ) [ ] RL 2 = (4.7kΩ 91kΩ 120kΩ) rπ 3 + (β o3 + 1)(2.2kΩ 250Ω) = 4.31kΩ [734Ω + 81(225Ω)] = 3.51kΩ Avt 2 = − Avt 3 = 150(3.51kΩ) β o2 RL 2 =− = −2.17 rπ 2 + (β o2 + 1)1.6kΩ 2.39kΩ + (151)1.6kΩ 81(2.2kΩ 250Ω) ⎞ ⎛ 1MΩ = 0.961 | Av = −⎜ ⎟(−1.05)(−2.17)(0.961) = +2.17 ⎝10kΩ + 1MΩ ⎠ 734 + 81(2.2kΩ 250Ω) ⎛R + r ⎞ ⎛ ⎞ β o2 RE 2 Rout = (3300Ω) ⎜ th 3 π 3 ⎟ | Rth 3 = RI 3 Ro2 =RI 3 ro2 ⎜1+ ⎟ ≅ RI 3 = 4.31kΩ ⎝ β o3 + 1 ⎠ ⎝ Rth 2 + rπ 2 + RE 2 ⎠ ⎛ 4.31+ 1.00 ⎞ Rout = (3.30kΩ) ⎜ kΩ⎟ = 64.3Ω ⎠ ⎝ 81 14.105 *Problem 14.105 - Use the listing from Problem 14.103, but remove C2 and C4. Result: Av = VM(11) = +2.20 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-49 14.106 100kΩ = 1.63V | REQ1 = 100kΩ 820kΩ = 89.1kΩ 100kΩ + 820kΩ ⎞ ⎛ 1.63 - 0.7 101 = 319 µA | VCE1 = 15 − ⎜18kΩ + 2kΩ⎟IC = 8.61 V IC1 = 100 ⎠ ⎝ 89.1kΩ +101(2kΩ) 100 Q1 : VEQ1 = 15 gm1 = 40(319 µA) = 12.8mS | rπ 1 = 100 (70 + 8.61)V = 246kΩ = 7.81kΩ | ro1 = 319 µA 12.8mS 43kΩ = 3.18V | REQ 2 = 160kΩ 43kΩ = 33.9kΩ 43kΩ + 160kΩ ⎞ ⎛ 3.18 - 0.7 101 =1.27 mA | VCE 2 = 15 − ⎜ 4.7kΩ + 1.6kΩ⎟IC = 6.98 V IC 2 = 100 ⎠ ⎝ 33.9kΩ +101(1.6kΩ) 100 Q2 : VEQ 2 = 15 gm 2 = 40(1.27mA) = 50.8mS | rπ 2 = 100 (70 + 6.98)V = 60.6kΩ = 1.97kΩ | ro2 = 1.27mA 50.8mS 1.2MΩ = 8.53V | REQ 3 = 1.2MΩ 910kΩ = 518kΩ 1.2MΩ + 910kΩ 2ID 3 + 3000ID 3 → ID 3 = 1.87mA | VGS 3 − VTN 3 = 1.93V 8.53 = VGS 3 + 3000ID 3 =1 + 0.001 M 3 : VEQ 3 = 15 VDS 3 = 15 − 3000ID 3 = 9.39V | gm 3 = 2(0.001)(0.00187) = 1.93mS ⎛ Rin ⎞ Av = ⎜ ⎟ Avt1 Avt 2 Avt 3 | Rin = 820kΩ 100kΩ rπ 1 = 820kΩ 100kΩ 7.81kΩ = 7.18kΩ ⎝ RI + Rin ⎠ Avt1 = −gm1 (RC1 RB 2 rπ 2 ) = −12.8mS (18kΩ 33.9kΩ 1.97kΩ) = −21.6 Avt 2 = −gm 2 (RC 2 RG 3 ) = −50.8mS (4.7kΩ 518kΩ) = −237 Avt 3 = gm 3 (RE 3 RL ) = 1.93mS (3.0kΩ 250Ω) 1+ gm 3 (RE 3 RL ) 1+ 1.93mS (3.0kΩ 250Ω) = 0.308 ⎞ ⎛ 7.18kΩ Av = ⎜ ⎟(−21.6)(−237)(0.308) = 659 ⎝10kΩ + 7.18kΩ ⎠ ⎛ Rin ⎞ v gs3 = v g 3 (1− Avt 3 ) = ⎜ ⎟ Avt1 Avt 2v i (1− Av 3 ) ≤ 0.2(VGS 3 − VTN 3 ) ⎝ RI + Rin ⎠ vi ≤ 0.2(1.93) = 261µV 0.418(21.6)(237)(1− 0.308) The gain is reduced rather than improved. The signal range increased since the gain was reduced. 14-50 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.107 *Problem 14.107 - Multistage Amplifier – Figure P14.106 VCC 12 0 DC 15 VI 1 0 AC 1 RI 1 2 10K *For output resistance *VI 1 0 AC 0 *VO 11 0 AC 1 C1 2 3 22U R1 12 3 820K R2 3 0 100K Q1 5 3 4 NBJT RE1 4 0 2K C2 4 0 22U RC1 12 5 18K C3 5 6 22U R3 12 6 160K R4 6 0 43K Q2 8 6 7 NBJT RC 12 8 4.7K RE2 7 0 1.6K C4 7 0 22U C5 8 9 22U R5 12 9 910K R6 9 0 1.2MEG M3 12 9 10 10 NMOSFET RE3 10 0 3K C6 10 11 22U RL 11 0 250 .OP .AC LIN 1 3KHZ 3KHZ .MODEL NMOSFET NMOS VTO=1 KP=.001 LAMBDA=0.02 .MODEL NBJT NPN IS=1E-16 BF=100 VA=70 .PRINT AC VM(3) VP(3) IM(VI) IP(VI) VM(11) VP(11) IM(C6) IP(C6) .END VM(3) 1 Results : Av = VM(11) = +711 | Rin = = 8.29 kΩ | Rout = = 401 Ω IM(VI) IM(C6) © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-51 14.108 Rin = R1 R2 [rπ 1 + (β o1 + 1)RE1 ] = 100kΩ 820kΩ [7.81kΩ + 101(2kΩ)] = 62.66kΩ Avt1 = − β o1 (RC1 RB 2 RI 2 ) | RI 2 = rπ 2 + (β o2 + 1)RE 2 = 1.97kΩ + 101(1.6kΩ) = 164kΩ rπ 1 + (β o1 + 1)RE1 R3 R4 = 43kΩ 160kΩ = 33.9kΩ | Avt1 = − 100(18kΩ 33.9kΩ 164kΩ) 7.81kΩ + 101(2kΩ) RG 3 = R5 R6 = 1.2MΩ 910kΩ = 518kΩ | Avt 2 = − Avt 3 = gm 3 (RE 3 RL ) = 1.93mS (3.0kΩ 250Ω) 1+ gm 3 (RE 3 RL ) 1+ 1.93mS (3.0kΩ 250Ω) = −6.69 100(4.7kΩ 518kΩ) β o2 (RC 2 RG 3 ) =− = −2.85 rπ 2 + (β o2 + 1)RE1 1.97kΩ + 101(1.6kΩ) = 0.308 ⎛ ⎞ ⎛ ⎞ Rin 62.6kΩ Av = ⎜ ⎟(−6.69)(−2.85)(0.308) = 5.05 ⎟ Avt1 Avt 2 Avt 3 = ⎜ ⎝ 10kΩ + 62.6kΩ ⎠ ⎝10kΩ + Rin ⎠ 14-52 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.109 Note that the equivalent circuits are the same for Q1 and Q2 . 180kΩ 15V = 5.63V | REQ = 180kΩ 300kΩ = 113 kΩ 180kΩ + 300kΩ 5.63 − 0.7 V IB = = 2.31µA | IC = 100I B1 = 232µA | I E = 101I B1 = 234µA 113 + 101(20) kΩ VEQ = VCE = 15 − 2x10 4 I E − 2x10 4 IC = 5.71V rπ = 100(0.025V ) 232µA = 10.8kΩ | ro = RI v1 232µA v2 Q 20 k Ω 20 k Ω Q 1 2kΩ vi (70 + 5.71)V = 326kΩ 2 300 k Ω 100 k Ω 16.7 k Ω 180 k Ω R 2kΩ 113 k Ω 180 k Ω R I1 L 300 k Ω =17.0 k Ω ⎛ Rin ⎞ Av = ⎜ ⎟ Avt1 Avt 2 ⎝ 2kΩ + Rin ⎠ Avt1 = 100(17kΩ 10.8kΩ) β o1 (RI1 rπ 2 ) v2 =− =− = −3.10 v1 rπ 1 + (β o1 + 1)R5 10.8kΩ + (101)2kΩ Avt 2 = vo = −gm 2 RL | RL = 100kΩ 20kΩ = 16.7kΩ | Avt 2 = −40(232µA)(16.7kΩ) = −155 v2 Rin = RB1 (rπ 1 + (β o1 + 1)R5 ) = 300kΩ 180kΩ [10.8kΩ + (101)2kΩ] = 73.6kΩ ⎛ 73.6kΩ ⎞ Av = ⎜ ⎟(−3.10)(−155) = +468 | Rout = 20kΩ ro2 = 20kΩ 326kΩ = 18.8kΩ ⎝ 2kΩ + 73.6kΩ ⎠ © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-53 14.110 The ac equivalent circuit from Problem 14.109 becomes: v1 Q 2k Ω v2 20 k Ω Q 1 2 100 k Ω 300 k Ω vi vo 20 k Ω 16.7 k Ω 180 k Ω RL 20 k Ω ( 113 k Ω ) 180 k Ω 300 k Ω 20 k Ω RI1 =17.0 k Ω [ ] Avt1 = 100 17kΩ (10.8kΩ + (101)20kΩ) β o RI1 [rπ 2 + (β o2 + 1)R6 ] v2 =− =− = −0.830 v b1 rπ 1 + (β o1 + 1)R5 10.8kΩ + (101)20kΩ Avt 2 = 100(16.7kΩ) β o2 RL vo =− =− = −0.822 v2 rπ 2 + (β o2 + 1)R6 10.8kΩ + (101)20kΩ Rin Avt1 Avt 2 | Rin = 113kΩ (rπ 1 + (β o1 + 1)R5 ) = 113kΩ (10.8kΩ + (101)20kΩ) = 107kΩ RI + Rin 107kΩ Av = (−0.830)(−0.822) = +0.670 2kΩ + 107kΩ The voltage gain is completely lost. | Rout ≅ 20kΩ Av = 14-54 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.111 *Problem 14.111 - Multistage Amplifier – Figure P14.109 VCC 11 0 DC 15 VI 1 0 AC 1 RI 1 2 2K *For output resistance *VI 1 0 AC 0 *VO 10 0 AC 1 C1 2 3 10U R1 3 0 180K R2 11 3 300K Q1 6 3 4 NBJT RE1 4 5 2K RE2 5 0 18K C2 5 0 10U RC1 11 6 20K C3 6 7 10U R3 7 0 180K R4 11 7 300K Q2 9 7 8 NBJT RC2 11 9 20K RE3 8 0 20K C4 8 0 10U C5 9 10 10U RL 10 0 100K .OP .AC LIN 1 5KHZ 5KHZ .MODEL NMOSFET NMOS VTO=1 KP=.001 LAMBDA=0.02 .MODEL NBJT NPN IS=1E-16 BF=100 VA=70 .PRINT AC VM(3) VP(3) IM(VI) IP(VI) VM(10) VP(10) IM(C5) IP(C5) .END VM(3) 1 Results : Av = VM(10) = +454 | Rin = = 74.7 kΩ | Rout = = 18.8 kΩ IM(VI) IM(C5) © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-55 14.112 ⎛ Rin ⎞ Av = ⎜ ⎟ Avt1 Avt 2 ⎝ 2kΩ + Rin ⎠ v Avt1 = 2 = −gm1 (RI1 rπ 2 ) = −40(232µA)(17kΩ 10.8kΩ) = −61.3 v1 v Avt 2 = o = −gm 2 RL | RL = 100kΩ 20kΩ = 16.7kΩ | Avt 2 = −40(232µA)(16.7kΩ) = −155 v2 Rin = RB1 rπ 1 = 300kΩ 180kΩ 10.8kΩ = 10.0kΩ ⎛ 10.0kΩ ⎞ Av = ⎜ ⎟(−61.3)(−155) = +7920 | Rout = 20kΩ ro2 = 20kΩ 326kΩ = 18.8kΩ ⎝ 2kΩ + 10.0kΩ ⎠ 14.113 0.05 2 (VGS + 2) and VGS = −1800ID M1: Assume saturation: ID = 2 0.05 2 VGS = −1800 (VGS + 2) or 45VGS2 + 181VGS + 180 = 0 2 VGS = −2.22V,−1.80V | VGS = −1.80 V and ID =1 mA VDS = 20 −15000(0.001) −1800(0.001) = 3.2 V > VGS − VTN 0.05 2 (VGS + 2) and VGS = −2500ID M2: Assume saturation: ID = 2 0.05 2 VGS = −2500 (VGS + 2) or 62.5VGS2 + 251VGS + 250 = 0 2 VGS = −1.83 V and ID = 0.723 mA VDS = 20 − 2500(0.723mA) =18.2 V > VGS − VTN gm1 = 2(0.05)(0.001) = 10.0mS | gm 2 = 2(0.05)(7.23x10−4 ) = 8.50mS Rin = 1800 1 1 = 1800 100 = 94.7Ω | Rout = 2500 = 2500 118 = 113Ω gm1 gm 2 Avt1 = +gm1 (15kΩ 1MΩ) = 0.01S (14.8kΩ) = 148 Avt 2 = + gm 2 (2.5kΩ 10kΩ) 1+ gm 2 (2.5kΩ 10kΩ) =+ 8.5x10−3 (2.5kΩ 10kΩ) 1+ 8.5x10−3 (2.5kΩ 10kΩ) = 0.944 Av = Avt1 Avt 2 = +140 14-56 © R. C. Jaeger & T. N. Blalock - February 20, 2007 14.114 100kΩ = 0V | REQ = 100kΩ 100kΩ = 50kΩ 100kΩ + 100kΩ 0 − 0.7 − (−15) = 22.3µA | IC = 2.78 mA | I E = 2.81 mA IB = 50kΩ + 126(4.7kΩ) VEQ = −15 + 30 VCE = 30 − 2000IC − 4700I E = 11.4 V | rπ = ro = (50 + 11.4)V = 22.1kΩ 125(0.025V ) 2.78mA = 1.12kΩ | RB = R1 R2 = 100kΩ 100kΩ = 50kΩ 2.78mA Rin = RB rπ + (β o + 1)RL = 50kΩ 1.12kΩ + (126)3.34kΩ = 44.7 kΩ [ (R B Rout = RE ro ) ] RI + rπ βo + 1 [ ] (44.7kΩ 600Ω)+ 1.12kΩ = 13.5 Ω = 4.7kΩ 22.1kΩ 126 R1S = RI + Rin = 45.3kΩ R2S = R3 + Rout = 24.0kΩ R3S ≅ RC = 2kΩ ⎤ 1 ⎡ 1 1 ⎢ −5 ⎥ = 0.492 Hz SPICE result : f L = 0.39Hz fL ≅ + 2π ⎢⎣10 (45.3kΩ) 47x10−6 (24.0kΩ)⎥⎦ Note that C3 is not in the signal path and doesn't contribute to f L . 14.115 Use C3 = 2.2 µF (10 − 0.7)V = 1.43 µA | I = 114 µA | V = 20 − 39000I − 68000I = 7.71 V IB = C CE C E 1MΩ + (80 + 1)68kΩ Active region is correct. | rπ = 81(0.025V ) 114µA = 17.8 kΩ | ro = 75 + 7.71 = 726 kΩ 114µA RL = 500kΩ 39kΩ 726kΩ = 34.5kΩ | Rin = RB rπ = 1MΩ 17.8kΩ = 17.5 kΩ ⎛ Rin ⎞ ⎛ ⎞ 17.5kΩ Av = −g m RL ⎜ ⎟ = 40(0.114mA)(34.5kΩ)⎜ ⎟ = −153 ⎝ 500Ω + 17.5kΩ ⎠ ⎝ RI + Rin ⎠ Rout = RC ro = 39kΩ 726kΩ = 37.0 kΩ R1S = RI + Rin = 18.0kΩ R3S = Rout + R3 = 537kΩ R2S = RE (R B ) RI + rπ βo + 1 = 68kΩ (1MΩ 500Ω)+ 17.8kΩ = 225Ω 81 ⎤ 1 1 ⎡ 1 1 ⎥ = 19.2 Hz ⎢ + + fL ≅ 2π ⎢⎣2.2µF (18.0kΩ) 47µF (225Ω) 2.2µF (537kΩ)⎥⎦ © R. C. Jaeger & T. N. Blalock - February 20, 2007 SPICE result : f L = 18 Hz 14-57 14.116 62kΩ = 9.07V | REQ = 62kΩ 20kΩ = 15.1kΩ 62kΩ + 20kΩ 12 − 0.7 − 9.07 IB = = 4.19µA | IC = 314 µA | I E = 319 µA 15.1kΩ + 76(6.8kΩ) (a) VEQ = 12 VEC = 12 −16000IC − 6800I E = 4.81 V 75(0.025) 60 + 4.81 = 206kΩ | r = = 5.97kΩ π 314x10−6 314x10−6 Rin = 15.1kΩ 5.97kΩ = 4.28 kΩ | Rout = ro 16kΩ = 14.8 kΩ | g m = 40IC = 12.6 mS ro = R1S = RI + Rin = 5.28kΩ R3S = Rout + R3 = 115kΩ R2S = RE fL ≅ (R B ) RI + rπ βo + 1 = 6.8kΩ (15.1kΩ 1kΩ)+ 5.97kΩ = 90.0Ω 76 ⎤ 1 1 ⎡ 1 1 ⎢ ⎥ = 51.5 Hz + + 2π ⎢⎣2.2µF (5.28kΩ) 47µF (90.0Ω) 10µF (115kΩ)⎥⎦ SPICE result : f L = 43.8 Hz 14.117 500kΩ = 4.73V | REQ = R1 R2 = 500kΩ 1.4 MΩ = 368kΩ 500kΩ + 1.4 MΩ Assume Active Region Operation VEQ = 18 2I D + 27000I D → I D = 113 µA 5x10−4 = 18 − (27000 + 75000)I D = 6.47 V > 3.73 V - Active region is correct. 4.73 = VGS = 27000I D → 4.73 = 1+ VDS 50 + 6.47 = 500kΩ | g m = 2 500x10−6 113x10−6 1+ 0.02(6.47) = 357µS −6 113x10 RL = ro RD 470kΩ = 500kΩ 75kΩ 470kΩ = 57.3kΩ ro = ( )( )[ ] Rin = R1 R2 = 500kΩ 1.4 MΩ = 368kΩ | Rout = ro 75kΩ = 65.2 kΩ R1S = RI + Rin = 369kΩ R3S = Rout + R3 = 535kΩ R2S = RS 1 1 = 27kΩ = 2.54kΩ gm 0.357mS ⎤ 1 ⎡ 1 1 1 ⎢ ⎥ = 1.56 Hz fL ≅ + + 2π ⎢⎣2.2µF (369kΩ) 47µF (2.54kΩ) 10µF (535kΩ)⎥⎦ 14-58 © R. C. Jaeger & T. N. Blalock - February 20, 2007 SPICE result : f L = 1.22 Hz 14.118 2.5x10−4 2 2 10 + VGS VGS + 1) | = 1.25x10−4 (VGS + 1) → VGS = −2.358V ID = ( 2 33kΩ 10 + VGS ID = = 232µA | VDS = −10 + 0.232mA(24kΩ)− 2.36 = −6.79V | Pinchoff region is correct. 33kΩ 50 + 6.79 = 245kΩ g m = 2 2.5x10−4 2.32x10−4 1+ 0.02(6.79) = 0.363mS ro = 2.32x10−4 1 Rin = 33kΩ = 2.69 kΩ | R1S = RI + Rin = 3.19kΩ | R2S ≅ RD + R3 = 124kΩ gm ⎤ 1 1 ⎡ 1 ⎥ = 5.94 Hz SPICE result : f L = 5.00 Hz ⎢ fL ≅ + 2π ⎢⎣10µF (2.69kΩ) 47µF (124kΩ)⎥⎦ ( ) ( )( )[ ] 14.119 (12 − 0.7)V = 2.69 µA | I = 135 µA | V 100kΩ + (51)82kΩ 50(0.025V ) Active region is correct. r = = 9.26 kΩ IB = C π [ ( R1S = RB rπ + (β o + 1) RE RI CE 135µA = 24 − 39000IC − 82000I E = 7.58 V | ro = 50 + 7.58 = 427 kΩ 135µA )]= 100kΩ [9.26kΩ + (51)(82kΩ 500Ω)]= 25.7kΩ rπ 9.26kΩ = 500 + 82kΩ = 681Ω | R3S = RC + R3 = 139kΩ 51 βo + 1 ⎤ 1 ⎡ 1 1 1 ⎢ ⎥ = 6.40 Hz SPICE result : f L = 5.72 Hz fL ≅ + + 2π ⎢⎣4.7µF (25.7kΩ) 47µF (681Ω) 10µF (139kΩ)⎥⎦ R2S = RI + RE 14.120 2 5x10−4 VGS + 2) → I D = 32.2 µA ( 2 = 15 − (20000 + 51000)I D = 12.7 V > 0.36 V - Active Region is correct. Assume Active Region operation. VGS = −51000I D I D = VDS ( )( )[ ] g m = 2 5x10−4 32.2x10−6 1+ 0.02(12.70) = 0.201mS | Rin = 51kΩ 1 = 4.53kΩ gm 50 + 12.7 = 1.95MΩ R1S = RI + Rin = 5.53kΩ R2 S ≅ RD + R3 = 30kΩ 32.2x10−6 ⎤ 1 1 ⎡ 1 ⎢ ⎥ = 13.2 Hz SPICE result : f L = 12.8 Hz fL ≅ + 2π ⎢⎣2.2µF (5.53kΩ) 47µF (30kΩ)⎥⎦ ro = © R. C. Jaeger & T. N. Blalock - February 20, 2007 14-59 14.121 The power supply should be +16 V. Assume Active Region operation. Since there is no negative feedback (RS = 0), we should include the effect of channel - length modulation. VGS = 0 2 4x10−4 −5) (1+ 0.02VDS ) and VDS = 16 −1800I D → I D = 5.59 mA ( 2 = 16 −1800I D = 5.93 V > 5 V - Active region is correct. ID = VDS 50 + 5.93 = 10.0kΩ Rin = 10.0 MΩ | Rout = RD ro = 1.52 kΩ 5.59x10−3 R1S = RI + Rin = 10.0 MΩ R2 S = Rout + R3 = 37.5kΩ ⎤ 1 ⎡ 1 1 ⎢ ⎥ = 0.497 Hz SPICE result : f L = 0.427 Hz + fL ≅ 2π ⎢⎣2.2µF (10.0 MΩ) 10µF (37.5kΩ)⎥⎦ ro = 14.122 Use C1 = C2 = C3 = 1 µF 0.05 2 (VGS + 2) and VGS = −1800ID M1: Assume saturation: ID = 2 2 0.05 VGS + 2) or 45VGS2 + 181VGS + 180 = 0 VGS = −1800 ( 2 VGS = −2.22V ,−1.80V | VGS = −1.80 V and I D = 1 mA VDS = 20 −15000(0.001)−1800(0.001) = 3.2 V > VGS − VTN 0.05 2 (VGS + 2) and VGS = −2500ID M2: Assume saturation: ID = 2 2 0.05 VGS + 2) or 62.5VGS2 + 251VGS + 250 = 0 VGS = −2500 ( 2 VGS = −1.83 V and I D = 0.723 mA VDS = 20 − 2500(0.723mA) = 18.2 V > VGS − VTN ( ) g m1 = 2(0.05)(0.001) = 10.0mS | g m2 = 2(0.05) 7.23x10−4 = 8.50mS R1S = Rin = 1800 1 = 1800 100 = 94.7Ω | R2 S = 15kΩ + 1MΩ = 1.02 MΩ g m1 1 = 2500 118 = 113Ω | R3 S = 10kΩ + Rout = 10.1kΩ g m2 ⎤ 1 ⎡ 1 1 1 ⎥ = 1.42 kHz SPICE result : f L = 1.68 kHz ⎢ fL ≅ + + 2π ⎢⎣1µF (113Ω) 1µF (1.02 MΩ) 1µF (10.1kΩ)⎥⎦ Rout = 2500 14-60 © R. C. Jaeger & T. N. Blalock - February 20, 2007 CHAPTER 15 15.1 (a) I C = αF IE = 1 β F 12 − VBE 1 ⎛100 ⎞⎛ 12 − 0.7 ⎞ = ⎜ = 20.7 µA | VC = 12 − 3.3x105 IC = 5.17V ⎟⎜ 5⎟ 2 β F + 1 REE 2 ⎝ 101 ⎠⎝ 2.7x10 ⎠ VCE = VC − (−0.7V ) = 5.87V | Q − Point = (20.7µA, 5.87V ) (b) A = −g m RC = −40(20.7µA)(330kΩ)= −273 dd Rid = 2rπ = 2 (c) A cc =− Add = − IC =2 100(0.025V ) E = 243 kΩ | Rod = 2RC = 660 kΩ g m RC −137 = −137 | Acd = Acc | CMRR = = 227 or 47.1 dB (very low) 2 −0.604 2 15.2 20.7µA 100(330kΩ) β o RC =− = −0.604 rπ + (β o + 1)2REE 122kΩ + 2(101)270kΩ rπ + (β o + 1)2REE Ric = (a) I β oVT = 122kΩ + 2(101)270kΩ 2 = 27.3 MΩ 1 ⎛ 1.5 − 0.7 ⎞ V 60 = ⎜ = 5.33µA | IC = α F I E = I E = 5.25µA 3 ⎟ 2 ⎝ 75x10 ⎠ Ω 61 VCE = 1.5 −105 IC − (−0.7)= 1.68V | Q - Pt : (5.25µA, 1.68V ) (b) g m Acc = − = 40IC = 0.210mS | rπ = 60 = 286kΩ | Add = −g m RC = −0.210mS (100kΩ)= −21.0 gm 60(100kΩ) β o RC =− = −0.636 rπ + (β o + 1)2REE 286kΩ + 61(150kΩ) For differential output : CMRR = −21.0 =∞ 0 −21.0 2 For single - ended output : CMRR = = 16.5, a paltry 24.4 dB! −0.636 Rid = 2rπ = 572kΩ | Ric = rπ + (β o + 1)2REE Rod = 2RC = 200 kΩ | Roc = 2 = 286 + 61(150) 2 kΩ = 4.72 MΩ RC = 50kΩ 2 15.3 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-1 *Problem 15.3 VCC 2 0 DC 12 VEE 1 0 DC -12 VIC 8 0 DC 0 VID1 4 8 AC 0.5 VID2 6 8 AC -0.5 RC1 2 3 330K RC2 2 7 330K Q1 3 4 5 NBJT Q2 7 6 5 NBJT REE 5 1 270K .MODEL NBJT NPN BF=100 VA=60 IS=1FA .OP .AC LIN 1 1KHZ 1KHZ .PRINT AC IM(VID1) IP(VID1) VM(3,7) VP(3,7) .TF V(7) VIC .END 1 Results : Add = VM(3,7) = −241 | Rid = = 269 kΩ | Acc = -0.602 | Ric = 23.2 MΩ IM(VID1) Problem15.45(b)-Transient-7 +0.000e+000 +1.000m +2.000m Time (s) +3.000m +4.000m +6.000 +4.000 +2.000 +0.000e+000 -2.000 -4.000 -6.000 V(IVOUT) Simulation results from B2SPICE. Problem15.3(b)-Fourier-Table FREQ mag phase norm_mag norm_phase +0.000 +49.786n +0.000 +0.00 +0.000 +1.000k +5.766 +180.000 +1.000 +0.000 +2.000k +99.572n +93.600 +17.268n -86.400 +3.000k +80.305m -180.000 +13.927m -360.000 +4.000k +99.572n +97.200 +17.268n -82.800 +5.000k +1.161m +179.993 +201.326u -7.528m +6.000k +99.572n +100.800 +17.268n -79.200 +7.000k +13.351u -179.005 +2.315u -359.005 +8.000k +99.572n +104.400 +17.268n -75.600 Using the Fourier analysis capability of SPICE, THD = 1.39% 15-2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.4 (a) I E = 18V − 0.7V ( ) 2 4.7 x10 Ω 4 = 184 µA | IC = α F I E = 100 I E = 182 µA 101 VCE = 18 − 105 IC − (−0.7)= 0.92 V | Q - point : (182 µA, 0.92 V ) Note that RC is quite large and the common - mode input range is poor. More realistic choices might be 47 kΩ or 51 kΩ 100 (b) g m = 40 IC = 7.28 mS | rπ = g = 13.7 kΩ | Add = −g m RC = −7.28mS (100kΩ)= −728 m Acc = − 100(100 kΩ) β o RC =− = −1.05 rπ + (β o + 1)2 REE 13.7 kΩ + 101(94 kΩ) For differential output : CMRR = −33.7 =∞ 0 −728 For single - ended output : CMRR = 2 = 346, a paltry 50.8 dB! −1.05 Rid = 2rπ = 27.4 kΩ | Ric = rπ + (β o + 1)2 REE Rod = 2 RC = 200 kΩ | Roc = 2 = 13.7 + 101(94) 2 kΩ = 4.75 MΩ RC = 50 kΩ 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-3 15.5 (a) I C 1 ⎛ β ⎞⎛ 12 − VBE ⎞ 1 ⎛ 100 ⎞⎛ 12 − 0.7 ⎞ = α F I E = ⎜ F ⎟⎜ ⎟= ⎜ ⎟⎜ ⎟ = 20.7 µA 2 ⎝ β F + 1⎠⎝ REE ⎠ 2 ⎝ 101 ⎠⎝ 2.7 x105 ⎠ VC1 = VC 2 = 12 − 2.4 x105 IC = 7.03V | VCE = VC − (−0.7V )= 7.73V Q − Point = (20.7µA, 7.73V ) | rπ = Acc = − 100(0.025V ) 20.7 µA = 121kΩ 100(240 kΩ) β o RC 5.000 + 5.000 = = −0.439 | vic = = 5.00V 2 rπ + (β o + 1)2 REE 121kΩ + (101)540kΩ vic = 5 V , vC1 = vC 2 = 7.03 + Accvic = 7.03 − 0.439(5) = 4.84 V Note that the BJT's are just beyond the edge of saturation! 1 β F ⎛ 5V − VBE − (−12V )⎞ 1 ⎛ 100 ⎞⎛17V − 0.7V ⎞ ⎟= ⎜ b I = α I = ( ) C F E 2 β + 1⎜⎜ ⎟ 2 ⎝ 101⎟⎠⎜⎝ 2.7 x105 ⎟⎠ = 29.9 µA R F EE ⎝ ⎠ VC1 = VC 2 = 12 − 2.4 x105 IC = 4.82 V | Part (a) has a small error of 0.02 mV (c) The common - mode signal voltage applied to the base - emitter junction is vbe = vic rπ 121kΩ =5 = 11.1 mV > 5mV . rπ + (β o + 1)2 REE 121kΩ + (101)540 kΩ A common - mode input voltage of 5 volts exceeds the small - signal limit. 15.6 We should first check the feasibility of the design using the Rule- of - Thumb estimates similar to those developed in Chapter 13 (Eq. (13.55)). The required Add = 794 (58 db). (This sounds fairly large - a significant fraction of the BJT amplification factor µf .) Even assuming we choose to drop all of the positive power supply voltage across RC (which provides no common - mode input range) : Add = g m RC = 40IC RL ≤ 40VCC = 40(9)= 360. Thus, a gain of 794 is not feasible with this topology! 15-4 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.7 We should first check the feasibility of the design using the Rule- of - Thumb estimates similar to those developed in Chapter 13 (Eq. (13.55)). The required Add = 200 (46 db). For symmetric supplies, Add ≅ 10(VCC + VEE ) = 240. Thus, a gain of 200 appears feasible. Rid = 2rπ = 1MΩ → rπ = 500kΩ | IC = IE = IC αF = β oVT rπ = 100(0.025V ) 500kΩ = 5.00 µA 101 V − VBE (12 − 0.7)V IC = 5.05µA | REE = EE = = 1.12 MΩ 100 2I E 2(5.05µA) Add = −g m RC = −200 (46dB) | RC = 200 200 = = 1.00 MΩ g m 40 5x10−6 ( ) Checking the collector voltage : VC = 12 − (990kΩ)(5µA)= 7V | Picking the closest 5% valuesfrom the table in the Appendix : REE = 1.1 MΩ and RC = 1 MΩ are the final design values. These values give IC = 5.09µA and Add = −204 (46.2dB). ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-5 15.8 (a) I = αF IE = αF C I EE 100 ⎛ 400µA ⎞ 4 = ⎜ ⎟ = 198µA | VCE = 12 − 3.9x10 IC − (−0.7)= 4.98V 2 101 ⎝ 2 ⎠ Q - point : (198µA,4.98V ) (b) g m = 40IC = 7.92mS | rπ = Acc = − 100 = 12.6kΩ | Add = −g m RC = −7.92mS (39kΩ)= −309 gm 100(39kΩ) β o RC =− = −0.0965 rπ + (β o + 1)2REE 12.6kΩ + 101(400kΩ) For a differential output : CMRR = −309 =∞ 0 −309 2 = 1600 or 64.1 dB For a single - ended output : CMRR = −0.0965 Rid = 2rπ = 25.2 kΩ | Ric = rπ + (β o + 1)2REE 12.6kΩ + 101(400kΩ) kΩ = 20.2 MΩ 2 2 ( Note that this value is approaching the βoro limit and hence is not really correct.) Rod = 2RC = 78.0 kΩ | Roc = = RC = 19.5 kΩ 2 50 + 4.98 = 278kΩ 198x10−6 Add = −g m RC ro = −7.92mS 39kΩ 278kΩ = −271 (c) r o = ( Acc ≅ − ) ( ) 100(39kΩ) β o RC =− = −0.0965 rπ + (β o + 1)2REE 12.6kΩ + 101(400kΩ) −271 =∞ 0 For differential output : CMRR = −271 2 For single - ended output : CMRR = = 1400 or 62.9 dB −0.0965 Rid = 2rπ = 25.2 kΩ | Ric = ( ) Rod = 2 RC ro = 68.4 kΩ | Roc = 15-6 ( rπ + (β o + 1) 2REE ro 2 CB RC Rout ( 2 )≅ R ) = 12.6kΩ + 101(164kΩ)kΩ = 8.29 MΩ C 2 2 ( ) CB = 19.5 kΩ since Rout ≅ µ f 2REE rπ = 24.4 MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.9 I EE 75 400µA = = 197µA | VC1 = VC 2 = 12 − 3.9x10 4 IC = 4.32V 76 2 2 = 4.32 − (−0.7)= 5.02V | Q - point : (197µA,5.02V ) IC = α F I E = α F VCE g m = 40IC = 7.88mS | rπ = Acc = − 75 = 9.52kΩ | Add = −g m RC = −7.88mS (39kΩ) = −307 gm 75(39kΩ) β o RC =− = −0.0962 rπ + (β o + 1)2REE 9.52kΩ + 76(400kΩ) 2.005 + 1.995 = 2.00V 2 0.01V v vC1 = VC1 + Add id + Accv ic = 4.32V − 307 − 0.0962(2V ) = 2.593 V 2 2 0.01V v − 0.0962(2V )= 5.663 V vC 2 = VC 2 − Add id + Accv ic = 4.32V + 307 2 2 vOD = 2.593 − 5.663 = −3.07 V vid = 2.005 −1.995 = 0.01V | v ic = VCB = VC1 + AccVIC − VIC ≥ 0 | VIC ≤ 15.10 Rid = 2rπ = 2(100)(0.025V ) 2β oVT I 101 → IC = 1.00µA | I EE = 2 C = 2 (1µA)= 2.02 µA 100 IC 5MΩ αF CMRR = g m REE = 105 → REE = 15.11 (a ) I C 4.32 = 3.94 V 1+ 0.0962 = αF IE = αF 105 = 2.5 GΩ ! 40(1.00µA) I EE 100 ⎛ 20µA ⎞ 5 = ⎜ ⎟ = 9.90µA | VC 2 = 10 − 9.1x10 IC = 0.991V 2 101 ⎝ 2 ⎠ g m = 40IC = 0.396mS | Add = −g m RC = −0.396mS (910kΩ) = −360 | REE = ∞ → Acc ≅ 0 vid + Accv ic | For vs = 0 : vC 2 = VC2 = 0.991 2 For v s = 2mV : vC 2 = 0.991V + 360(0.001V )− 0(0.001V )= +1.35 V vC 2 = VC 2 − Add (b) For v BC ≥ 0, vs − (0.991−180vs )≥ 0 → vs ≤ 0.991V = 5.48 mV 181 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-7 15.12 (a ) I C = αF IE = αF I EE 120 ⎛ 200µA ⎞ 5 = ⎜ ⎟ = 99.2µA | VO = 12 −1.10x10 IC = 1.09 V 2 121 ⎝ 2 ⎠ g m = 40IC = 3.97mS | Add = −g m RC = −3.97mS (110kΩ)= −437 | REE = ∞ → Acc ≅ 0 For vs = 0 : VO = 1.09 V and v o = − Add vid =0 2 0.001V = 0.219 V For vs = 1 mV : VO = 1.09 V and vo = −(−437) 2 ⎛ ⎞ A (b) For vCB ≥ 0, vs − ⎜⎝VO − 2dd vs ⎟⎠ ≥ 0 → vs ≤ 4.96 mV 15.13 *Problem 15.13 - Figure P15.11 VCC 2 0 DC 12 VEE 1 0 DC -12 V1 3 7 AC 1 V2 5 7 AC 0 VIC 7 0 DC 0 RC 2 6 110K Q1 2 3 4 NBJT Q2 6 5 4 NBJT IEE 4 1 DC 200U .MODEL NBJT NPN VA=60V BF=120 .OP .AC LIN 1 1KHz 1KHZ .PRINT AC IM(V1) IP(V1) VM(6) VP(6) .TF V(6) VIC .END 1 Results : Add = VM(6) = −193 | Rid = = 82.0 kΩ | Acc = +0.0123 | Ric = 45.8 MΩ IM(V1) Circuit 15.55-Transient-3 +0.000e+000 +1.000m +2.000m +3.000m +4.000m +5.000m Time (s) +6.000m +7.000m +8.000m +9.000m +13.000 +12.000 +11.000 +10.000 +9.000 +8.000 +7.000 +6.000 +5.000 *REAL(Vout)* Simulation results from B2SPICE. The amplifier is over driven causing the output to be distorted. Using the Fourier analysis capability of SPICE, THD = 16.9% 15.14 15-8 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 150 ⎡ 15 − 0.7 ⎤ ⎢ ⎥ = 47.4µA | VEC = 0.7 − −15 + 2x105 IC = 6.22V IC = α F I E = 151 ⎢⎣2(150kΩ)⎥⎦ ( ) Q - points : (47.4µA, 6.22V ) | g m = 40IC = 1.90mS | rπ = Add = −g m RC = −1.90mS (200kΩ) = −380 Acc = − 150 = 79.0kΩ gm 150(200kΩ) β o RC =− = −0.661 rπ + (β o + 1)2REE 79.0kΩ + 151(300kΩ) Rid = 2rπ = 158kΩ | Ric = rπ + (β o + 1)2REE 79.0kΩ + 151(300kΩ) = 22.7 MΩ 2 For a differential output : Adm = Add = −380 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = 2 = Add = −190 | Acm = Acc = −0.661 2 −190 = 287 or 49.2dB −0.661 15.15 IC = α F I E = 100 ⎡ 10 − 0.7 ⎤ ⎢ ⎥ = 10.7µA | VC1 = VC 2 = −10 + 5.6x105 IC = −4.01V 101 ⎢⎣2(430kΩ)⎥⎦ VEC = 0.7 − (−4.01) = 4.71V | g m = 40IC = 0.428mS | rπ = Add = −g m RC = −0.428mS (560kΩ)= −240 Acc = − 100 = 234kΩ gm 100(560kΩ) β o RC =− = −0.643 rπ + (β o + 1)2REE 234kΩ + 101(860kΩ) 1+ 0.99 = 0.995V 2 v 0.01V − 0.643(0.995V )= −5.850 V vC1 = VC1 + Add id + Accv ic = −4.01V − 240 2 2 0.01V v vC 2 = VC 2 − Add id + Accv ic = −4.01V + 240 − 0.643(0.995V ) = −3.450 V 2 2 −5.850 − 3.450 = −4.65 vOD = −5.850 − (−3.450)= −2.40 V | Note : Add vid = −2.40V and vOC = 2 Also note : vOC = VC + Accv ic = −4.01− 0.643(0.995V ) = −4.65V vid = 1− 0.99 = 0.01V | v ic = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-9 15.16 *Problem 15.16 – Figure P15.14 VCC 2 0 DC 10 VEE 1 0 DC -10 V1 4 8 AC 1 V2 6 8 AC 0 VIC 8 0 DC 0 RC1 5 1 560K RC2 7 1 560K Q1 5 4 3 PBJT Q2 7 6 3 PBJT REE 2 3 430K .MODEL PBJT PNP VA=60V BF=100 .OP .AC LIN 1 5KHz 5KHZ .PRINT AC IM(V1) IP(V1) VM(5,7) VP(5,7) .TF V(7) VIC .END 1 Add = VM(5,7) = −213 | Rid = = 511 kΩ IM(V1) 213 = 332 → 50.4dB Acc = −0.642 | Ric = 37.5 MΩ | CMRR = 0.642 15-10 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.17 IC = α F I EE 80 ⎛10µA ⎞ 5 = ⎜ ⎟ = 4.94µA | VEC = 0.7 − −3 + 3.9x10 IC = 1.77V 2 81 ⎝ 2 ⎠ ( ) Q - points : (4.94µA, 1.77V ) | g m = 40IC = 0.198mS | rπ = Add = −g m RC = −0.198mS (390kΩ)= −77.2 Acc = − 80 = 404kΩ gm 80(390kΩ) β o RC =− = −0.0385 rπ + (β o + 1)2REE 404kΩ + 81(10 MΩ) Rid = 2rπ = 808kΩ | Ric = Note that Ric is similar to rπ + (β o + 1)2REE 2 βoro 2 For example, if VA were 80V , = 808kΩ + 81(10 MΩ) 2 = 405 MΩ so that Ric = 405 MΩ will not be fully acheived. β oro 2 ≅ 80 ⎛ 80 ⎞ ⎜ ⎟ = 648 MΩ 2 ⎝ 4.94µA ⎠ For a differential output : Adm = Add = −77.2 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −38.6 | Acm = Acc = −0.661 2 −38.6 = 1000 or 60.0dB | VBC ≥ 0 requires VIC ≥ VC = −1.07V and −0.0385 Without detailed knowledge of the circuit for IEE , we can only estimate that VIC should not exceed VIC + 0.7 ≤ VCC − 0.7V which allows 0.7V for biasing I EE → −1.07V ≤ VIC ≤ +1.6V. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-11 15.18 IC = α F I EE 120 ⎛1mA ⎞ 4 = ⎜ ⎟ = 496µA | VC1 = VC 2 = −22 + 1.5x10 IC = −14.6V 2 121 ⎝ 2 ⎠ Checking VEC = 0.7 − (−14.6)= 15.3V | g m = 40IC = 19.8mS | rπ = Add = −g m RC = −19.8mS (15kΩ)= −297 Acc = − 120 = 6.06kΩ gm 120(15kΩ) β o RC =− = −0.0149 rπ + (β o + 1)2REE 6.06kΩ + 121(1MΩ) 0.01+ 0 = 0.005V 2 0.01V v − 0.0149(0.005V )= −16.09 V vC1 = VC1 + Add id + Accv ic = −14.6V − 297 2 2 0.01V v − 0.0149(0.005V )= −13.12 V vC 2 = VC 2 − Add id + Accv ic = −14.6V + 297 2 2 vOD = −16.09 − (−13.12)= −2.97 V | Note : Add v id = −2.97V vid = 0.01− 0 = 0.01V | v ic = −16.09 −13.12 = −14.6 and 2 = VC + Accvic = −14.60 − 0.0149(0.005V )= −14.6V Also note : vOC = vOC 15.19 IC = α F I E = 100 ⎡15V − 0.7V ⎤ 100 ⎢ ⎥ = 70.8µA | g m = 40IC = 2.83mS | rπ = = 35.3kΩ 101 ⎢⎣ 2(100kΩ) ⎥⎦ gm ⎛ ⎛ ∆R ⎞ ∆R ⎞ | vod = vc1 − vc2 = ic1⎜ R + ⎟ − ic2 ⎜ R − ⎟ 2 ⎠ 2 ⎠ ⎝ ⎝ vid ⎞⎛ ∆R ⎞ v ⎛ ∆R ⎞ ⎛ vod = −gm id ⎜ R + ⎟ − ⎜−gm ⎟⎜ R − ⎟ = −g m R vid | Add = −g m R = −283 2 ⎠ 2 ⎠ ⎝ 2⎝ 2 ⎠⎝ ⎛ ⎛ v ∆R ⎞ ∆R ⎞ Acd = od | vod = vc1 − vc2 = ic1⎜ R + ⎟ − ic2 ⎜ R − ⎟ 2 ⎠ 2 ⎠ vic ⎝ ⎝ Add = vod vid For a common - mode input, ic1 = ic2 = vod = − Acd = − rπ + (β o + 1)2REE vic ⎡⎛ ∆R ⎞ ⎛ ∆R ⎞⎤ β o∆R vic⎢⎜ R + v ic ⎟ −⎜R − ⎟⎥ = vod = − 2 ⎠ ⎝ 2 ⎠⎦ rπ + (β o + 1)2REE rπ + (β o + 1)2REE ⎣⎝ βo 100(100kΩ) ∆R βo R = −0.01 = −.00494 R rπ + (β o + 1)2REE 35.3kΩ + (101)200kΩ CMRR = 15-12 βo −283 = 57300 or 95.2 dB −0.00494 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.20 *Problem 15.20 – Figure P15.19 VCC 2 0 DC 15 VEE 1 0 DC -15 V1 4 8 AC 0.5 V2 6 8 AC -0.5 VIC 8 0 DC 0 RC1 2 5 100.5K RC2 2 7 99.5K Q1 5 4 3 NBJT Q2 7 6 3 NBJT REE 3 1 100K .MODEL NBJT NPN BF=100 .OP .AC LIN 1 100 100 .PRINT AC IM(V1) IP(V1) VM(5,7) VP(5,7) .TF V(5,7) VIC .END Results: Add = VM (5,7) = −274 | A cd = −0.00494 | CMRR = 55500 or 94.9 dB ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-13 15.21 For a differential - mode input : ⎛v ⎞⎛ ⎛ v ⎞⎛ ∆g ⎞ ∆g ⎞ vod = −⎜ id − ve ⎟⎜ g m + m ⎟ R + ⎜− id − ve ⎟⎜ g m − m ⎟ R = −g m R vid + ∆g m Rve 2 ⎠ 2 ⎠ ⎝2 ⎠⎝ ⎝ 2 ⎠⎝ ⎛ ⎞ ∆g vod = −g m R⎜ vid + m ve ⎟ | At the emitter node : gm ⎠ ⎝ ⎛ vid ⎞⎛ ⎞ ⎛ v ⎞⎛ ⎞ ∆g m ∆g + g π ⎟ + ⎜− id − ve ⎟⎜ g m − m + g π ⎟ − GEE ve = 0 ⎜ − ve ⎟⎜ g m + 2 2 ⎝2 ⎠⎝ ⎠ ⎝ 2 ⎠⎝ ⎠ 1 ∆g m 1 ∆g m β o REE ve = vid ≅ vid << v id | vod ≅ −g m R vid | Add ≅ −g m R = −300 2 g m rπ + (β o + 1)2REE 4 gm For a common - mode input : ⎛ ⎛ ∆g ⎞ ∆g ⎞ ∆g vod = −(vic − ve )⎜ g m + m ⎟ R + (vic − ve )⎜ g m − m ⎟ R = −∆g m R(vic − v e )= − m g m R(vic − ve ) 2 ⎠ 2 ⎠ gm ⎝ ⎝ ⎛ ⎞ ∆g ∆g At the emitter node : (vic − ve )⎜ g m + m + g π + g m − m + g π ⎟ − GEE ve = 0 2 2 ⎝ ⎠ ve = (β + 1)2R + (β + 1)2R o rπ Acd = EE o vic | vic − v e = EE rπ vic rπ + (β o + 1)2REE βo R gm R gm R v od ∆g ∆g ∆g =− m ≅− m =− m = −0.00499 vic g m rπ + (β o + 1)2REE g m 1+ 2g m REE g m 1+ 2g m REE −1 ⎡ ∆g ⎤ CMRR ≅ 2g m REE ⎢ m ⎥ = 60000 or 95.6 dB ⎣ gm ⎦ Note for Problems 15.22 - 15.37 The MATLAB m-file listed below 'FET Bias' can be used to help find the drain currents in the FET circuits in Problems 15.22 - 15.37. Use fzero('FET Bias',0) to find .ID function f=bias(id) kn=4e-4; vto=1; gamma=0.0; rss=62e3; vss=15; vsb=2*id*rss; vtn=vto+gamma*(sqrt(vsb+0.6)-sqrt(0.6)); f=vss-vtn-sqrt(2*id/kn)-vsb; 15-14 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.22 This solution made use of the m-file above. The solution to Problem 15.23 gives an example of direct hand calculation. 2 µA 12 − VGS K 12 − VGS ⇒ 2 n (VGS − VTN ) = and for Kn = 400 2 and VTN = 1V 2I S = 220kΩ 2 220kΩ V 2 2 12 − VGS = 88 VGS − 2VGS + 1 or 88VGS −175VGS + 76 = 0 and VGS = 1.348V ( ) 1 ⎛12 −1.35 ⎞ 5 ID = IS = ⎜ ⎟ = 24.2µA. VD = 12 − 3.3x10 (I D ) = 4.01V 2 ⎝ 220kΩ ⎠ VDS = 4.01− (−VGS )= 5.36V (> VGS − VTN ). Q - Point = (24.2µA, 5.36V ) ( ) 2 24.2x10−6 2I D gm = = = 1.39mS | Add = −g m RD = −1.39ms(330kΩ)= −45.9 VGS − VTN 0.348 Acc = − 1.39ms(330kΩ) g m RD = = −0.738 1+ 2g m RSS 1+ 2(1.39ms)(220kΩ) For a differential output : Adm = Add = −45.9 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −23.0 | Acm = Acc = −0.738 2 23.0 = 31.2 | CMRRdb = 29.8 dB | Rid = ∞ | Ric = ∞ 0.738 15.23 VSS − VGS = 2I D RSS | VGS = VTN + ( 2I D 2I D | VSS = 2I D RSS + VTN + Kn Kn ) 2I D → I D = 107µA | VGS − VTN = 0.731V 4x10−4 = 15 − (62kΩ)I D − (−VGS )= 10.1V > 0.731V - Active | Q - pt : (107µA, 10.1V ) 15 = 2I SS 62x103 + 1+ VDS gm = 2(107µA) 2I D = = 0.293mS | Add = −g m RD = −(0.293mS )(62kΩ)= −18.2 VGS − VTN 0.731V Acc = − (0.293mS )(62kΩ) = −0.487 g m RD =− 1+ 2g m RSS 1+ 2(0.293mS )(62kΩ) For a differential output : Adm = Add = −18.2 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −9.10 | Acm = Acc = −0.487 2 9.10 = 18.7 | CMRRdb = 25.4 dB | Rid = ∞ | Ric = ∞ 0.487 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-15 15.24 *Problem 15.24 - Figure P15.22 VCC 2 0 DC 12 VEE 1 0 DC -12 VIC 8 0 DC 0 VID1 4 8 AC 0.5 VID2 6 8 AC -0.5 RD1 2 3 330K RD2 2 7 330K M1 3 4 5 5 NFET M2 7 6 5 5 NFET REE 5 1 220K .MODEL NFET NMOS KP=400U VTO=1 .OP .AC LIN 1 1KHZ 1KHZ .PRINT AC IM(VID1) IP(VID1) VM(3,7) VP(3,7) .TF V(7) VIC .END Results : Add = VM(3,7) = −45.9 | Acc = −0.738 | CMRR = 31.2 | Rid = ∞ | Ric = ∞ (b) Results from B2SPICE Problem15.67(b)-Transient-0 +0.000e+000 (V) +1.000m +2.000m Time (s) +3.000m +4.000m +1.000 +500.000m +0.000e+000 -500.000m -1.000 V(IVOUT) Problem 15.24(b)-Fourier-Table FREQ mag phase +0.000 +1.000k +2.000k +3.000k +4.000k +5.000k -4.011 +586.074m +82.747u +90.858u +14.251n +9.695n norm_mag norm_phase +0.000 +0.000 +0.000 +180.000 +1.000 +0.000e+000 -90.000 +141.188u -270.000 +179.996 +155.029u -3.577m +93.958 +24.316n -86.042 +53.059 +16.541n -126.941 THD = 0.021% is very low due to the Level-1 square law model used in the simulation 15.25 15-16 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 First, we should check our rule - of - thumb. Since we have symmetric power supplies, Add ≅ VDD + VSS = 10 or 20 dB. We should be ok. Rod = 2RD = 5kΩ → RD = 2.5kΩ | Selecting closest 5% value : RD = 2.4kΩ 20 Add = −g m RD = 10 20 = 10 | g m = (4.17x10 ) = 348µA = 2(25x10 ) 2 −3 ID −3 RSS = 10 = 4.17mS = 2Kn I D 2400 | VGS = VTN + 2I DS = 1.16V Kn VSS − VGS 5 −1.16 = = 5.52kΩ | Selecting closest 5% value : RSS = 5.6kΩ 2I D 2(348µA) 15.26 (a ) This solution made use of the m - file listed above Prob. 15.22. VSS − VGS = 2I S RSS = 2I D RSS | VGS = VTN + VTN = VTO + γ (V SB ) + 0.6 − 0.6 = VTO + γ 2I D 2I D | VSS = 2I D RSS + VTN + Kn Kn ( 2I D RSS + 0.6 − 0.6 µA | VTO = 1V | γ = 0.75 V yields V2 = 3.01V | VGS = 3.69V Solving iteratively with RSS = 62kΩ | Kn = 400 I D = 91.3µA | VGS − VTN = 0.676V | VTN ) VDS = 15 − (62kΩ)I D − (−VGS )= 12.9V > 0.676V - Saturated | Q - pt : (91.3µA, 12.9V ) (b) g m Acc = − = 2(91.3µA) 2I D = = 0.270mS | Add = −g m RD = −(0.270mS )(62kΩ)= −16.7 VGS − VTN 0.676V (0.270mS )(62kΩ) = −0.486 assuming η = 0 g m RD =− 1+ 2g m (1+ η)RSS 1+ 2(0.270mS )(62kΩ) For a differential output : Adm = Add = −16.7 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −8.35 | Acm = Acc = −0.486 2 8.35 = 17.2 | CMRRdb = 24.7 dB | Rid = ∞ | Ric = ∞ 0.486 (c) For γ = 0, V TN I D = 107 µA = VTO | VSS = 2I D RSS + VTO + 2I D 2I D | 15 = 124000I D + 1+ Kn 4x10−4 VDS = 30 − 62000I D −128000I S = 10.1 V Saturated | Q - pt : (107 µA, 10.1 V ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-17 15.27 *Problem 15.27 - Figure P15.26 VCC 2 0 DC 15 VEE 1 0 DC -15 VIC 8 0 DC 0 VID1 4 8 AC 0.5 VID2 6 8 AC -0.5 RD1 2 3 62K RD2 2 7 62K M1 3 4 5 1 NFET M2 7 6 5 1 NFET REE 5 1 62K .MODEL NFET NMOS KP=400U VTO=1 PHI=0.6 GAMMA=0.75 .OP .AC LIN 1 1KHZ 1KHZ .PRINT AC IM(VID1) IP(VID1) VM(3,7) VP(3,7) .TF V(7) VIC .END Results: Add = VM(3,7) = −16.8 | Acc = −0.439 | CMRRdB = 25.6 dB | Rid = ∞ | Ric = ∞ (b) Problem15.70(b)-Transient-1 (V) +0.000e+000 +1.000m +2.000m Time (s) +3.000m +4.000m +400.000m +200.000m +0.000e+000 -200.000m -400.000m V(IVOUT) Problem15.27(b)-Fourier-Table FREQ +0.000 +1.000k +2.000k +3.000k +4.000k +5.000k 15-18 mag phase -345.019n +444.350m +35.476n +15.056u +23.789n +22.342n +0.000 +180.0 -30.192 -179.929 -50.644 -57.083 THD = 0.0034% norm_mag norm_phase +0.000 +0.000 +1.000 +0.000 +79.838n -210.192 +33.884u -359.929 +53.536n -230.643 +50.280n -237.083 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.28 This solution made use of the m - file listed above Prob. 15.22. (a) V 2I D 2I D | VSS = 2I D RSS + VTN + Kn Kn − VGS = 2I S RSS = 2I D RSS | VGS = VTN + SS VTN = VTO + γ (V SB ) + 0.6 − 0.6 = VTO + γ ( 2I D RSS + 0.6 − 0.6 µA | VTO = 1V | γ = 0.75 V yields V2 = 2.74V | VGS = 3.05V Solving iteratively with RSS = 220kΩ | Kn = 400 I D = 20.3µA | VGS − VTN = 0.319V | VTN ) VDS = 12 − (330kΩ)I D − (−VGS )= 8.35V > 0.319V - Active region | Q - pt : (20.3µA, 8.35V ) (b) g m = 2(20.3µA) 2I D = = 0.127mS | Add = −g m RD = −(0.127mS )(330kΩ)= −41.9 VGS − VTN 0.319V (0.127mS )(330kΩ) = −0.737 assuming η = 0 g m RD =− 1+ 2g m (1+ η)RSS 1+ 2(0.127mS )(220kΩ) Acc = − For a differential output : Adm = Add = −41.9 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −21.0 | Acm = Acc = −0.737 2 21.0 = 28.4 | CMRRdb = 29.1 dB | Rid = ∞ | Ric = ∞ 0.737 (c) For γ = 0, V TN I D = 24.2 µA = VTO | VSS = 2I D RSS + VTO + 2I D 2I D | 12 = 440000I D + 1+ Kn 4x10−4 VDS = 24 − 330000I D − 440000I S = 5.37 V Saturated | Q - pt : (25.2 µA, 5.37 V ) 15.29 ( 2 2x10−5 I SS 2I D (a) I D = 2 = 20µA | VGS = VTN + K = 1+ 4x10−4 n ) = 1.316V | V GS − VTN = 0.316V VDS = 9 − (300kΩ)I D − (−VGS )= 4.32V > 0.316V - Active region | Q - pt : (20µA, 4.32V ) (b) g m = Acc = − 2(20µA) 2I D = = 0.127mS | Add = −g m RD = −(0.127mS )(300kΩ) = −38.0 VGS − VTN 0.316V (0.127mS )(300kΩ) = −0.120 g m RD =− 1+ 2g m RSS 1+ 2(0.127mS )(1.25MΩ) For a differential output : Adm = Add = −38.0 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −19.0 | Acm = Acc = −0.120 2 19.0 = 158 | CMRRdb = 44.0 dB | Rid = ∞ | Ric = ∞ 0.120 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-19 15.30 ( 2 1.5x10−4 I SS 2I D (a) I D = 2 = 150µA | VGS = VTN + K = 1+ 4x10−4 n ) = 1.866V | VGS − VTN = 0.866V VDS = 15 − (75kΩ)I D − (−VGS ) = 5.62V > 0.866V - Active region | Q - pt : (150µA, 5.62V ) (b) g 2(150µA) 2I D = = 0.346mS | Add = −g m RD = −(0.346mS )(75kΩ)= −26.0 VGS − VTN 0.866V = m Acc = − (0.346mS )(75kΩ) = −0.232 g m RD =− 1+ 2g m RSS 1+ 2(0.346mS )(160kΩ) For a differential output : Adm = Add = −26.0 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −13.0 | Acm = Acc = −0.232 2 13.0 = 56.0 | CMRRdb = 35.0 dB | Rid = ∞ | Ric = ∞ 0.232 15.31 ( ) 2 2x10−5 I SS 2I D (a) I D = 2 = 20µA | VGS = VTN + K = VTN + 4x10−4 = VTN + 0.316V n VTN = VTO + γ (V SB ) ( 0.6 )→ V + 0.6 − 0.6 = 1+ 0.75 9 − VGS + 0.6 − 0.6 ( VGS − 0.316 = 1+ 0.75 9 − VGS + 0.6 − GS ) = 2.71V | VTN = 2.39V VDS = 9 − (300kΩ)I DS − (−VGS ) = 5.71V > 0.316V - Active region | Q - pt : (20µA, 5.71V ) (b) g m Acc = − = 2(20µA) 2I D = = 0.127mS | Add = −g m RD = −(0.127mS )(300kΩ)= −38.1 VGS − VTN 0.316V (0.127mS )(300kΩ) = −0.120 assuming η = 0 g m RD =− 1+ 2g m (1+ η)RSS 1+ 2(0.127mS )(1.25MΩ) For a differential output : Adm = Add = −38.1 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = 15-20 Add = −19.0 | Acm = Acc = −0.120 2 19.0 = 158 | CMRRdb = 44.0 dB | Rid = ∞ | Ric = ∞ 0.120 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.32 ( ) 2 1.5x10−4 I SS 2I D (a) I D = 2 = 150µA | VGS = VTN + K = VTN + 4x10−4 = VTN + 0.866V n VTN = VTO + γ (V SB ) ( 15 − V 0.6 )→ V + 0.6 − 0.6 = VTO + γ ( VGS − 0.866 = 1+ 0.75 15 − VGS + 0.6 − ) GS + 0.6 − 0.6 GS = 3.86V | VTN = 2.99V VDS = 15 − (75kΩ)I DS − (−VGS )= 7.61V > 0.866V - Active region | Q - pt : (150µA, 7.61V ) (b) g m Acc = − = 2(150µA) 2I D = = 0.346mS | Add = −g m RD = −(0.346mS )(75kΩ)= −26.0 VGS − VTN 0.866V (0.346mS )(75kΩ) = −0.233 assuming η = 0 g m RD =− 1+ 2g m (1+ η)RSS 1+ 2(0.346mS )(160kΩ) For a differential output : Adm = Add = −26.0 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −13.0 | Acm = Acc = −0.233 2 13.0 = 55.8 | CMRRdb = 34.9 dB | Rid = ∞ | Ric = ∞ 0.233 15.33 30 Add = −g m RD = 10 20 = 31.6 | First, we should check our rule - of - thumb. Since we have symmetric power supplies, Add ≅ (VDD + VSS ) = 15, within a factor of about 2. We should be ok if we reduce the value of VGS − VTN . (Remember, our rule - of - thumb used VGS − VTN = 1V.) | g m RD = 31.6 = 2I D RD VGS − VTN Maximum common - mode range requires minimum I D RD ⇒ minimum VGS − VTN Choosing VGS − VTN = 0.25V to insure strong inversion operation, I D RD = 0.25(31.6) 2 (0.25) (0.005) = 156µA 2I D → ID = Kn 2 2 = 3.95V | 0.25V = I SS = 2I D = 312 µA | RD = 3.95V = 25.3kΩ → 27kΩ, the nearest 5% value. 156µA ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-21 15.34 (a) I D Kp 2 1 ⎛ 18 − VGS ⎞ 18 + VGS µA = ⎜ VGS − VTP ) = and for K p = 200 2 and VTP = −1V ⎟⇒ ( 2 112kΩ 2 ⎝ 56kΩ ⎠ V 18 + VGS = 11.2(VGS + 1) → VGS = −2.19V | VGS − VTP = −1.19V | I D = 142µA 2 { [ ]} ) = 0.238mS VDS = − −VGS − (91kΩ)I D −18 = −7.27V ≤ −1.19V − Active region | Q - Point = (142µA, 7.27V ) (b) g m Acc = − ( )( = 2 2x10−4 1.42x10−4 | Add = −g m RD = −0.238mS (91kΩ)= −21.7 0.238mS (91kΩ) g m RD = = −0.785 1+ 2g m RSS 1+ 2(0.238mS )(56kΩ) For a differential output : Adm = Add = −21.7 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −10.9 | Acm = Acc = −0.785 2 10.9 = 13.9 | CMRRdb = 22.9 dB | Rid = ∞ | Ric = ∞ 0.785 15.35 *Problem 15.35 – Figure P15.34 VCC 2 0 DC 18 VEE 1 0 DC -18 VIC 8 0 DC 0 V1 4 8 AC 0.5 V2 6 8 AC -0.5 RD1 5 1 91K RD2 7 1 91K M1 5 4 3 3 PFET M2 7 6 3 3 PFET REE 2 3 56K .MODEL PFET PMOS KP=200U VTO=-1 .OP .AC LIN 1 3KHZ 3KHZ .PRINT AC IM(V1) IP(V1) VM(5,7) VP(5,7) .TF V(7) VIC .END Results : Add = VM(5,7) = −21.6 | Acc = −0.783 | CMRR = 13.8 | Rid = ∞ | Rid = ∞ 15-22 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.36 ( ) 2 2x10−5 I SS 2I D (a) I D = 2 = 20µA | VGS = VTP − K = VTP − 2x10−4 = VTP − 0.447V p { ( V + 0.6 − 0.6 )= −1− 0.6( 10 + V + 0.6 − 0.6 )} = −0.447 − { 1+ 0.6( 10.6 + V − 0.6 )}→ V = −2.67V | V = −2.23V VTP = − VTO − γ VGS BS GS GS GS [ ] 2(2x10 )(2x10 ) = 89.4µS TP VDS = VGS + −10 + (300kΩ)I D = −6.67V ≤ −0.447V - Active region | Q - pt : (20µA,-6.67V ) (b) g m Acc = − = −5 −4 | Add = −g m RD = −(89.4µS )(300kΩ)= −26.8 (89.4µS )(300kΩ) = −0.119 assuming η = 0 g m RD =− 1+ 2g m (1+ η)RSS 1+ 2(89.4µS )(1.25MΩ) For a differential output : Adm = Add = −26.8 | Acm = 0 | CMRR = ∞ For a single - ended output : Adm = CMRR = Add = −13.4 | Acm = Acc = −0.119 2 13.4 = 113 | CMRRdb = 41.0 dB | Rid = ∞ | Ric = ∞ 0.119 15.37 (a) I D = I SS = 10µA | VO = −12 + (820kΩ)I D = −3.80V | For vI = 0, vO = VO = −3.80 V 2 ( ) 2 10−5 2I D VGS = VTP + = 1− = 0.86 V | VGS − VP = −0.14V KP 10−3 VDS ≤ −0.14V for pinchoff. So VD ≤ −1 V for pinchoff. g m = 2(1mA)(10µA) = 141µS | Add = −g m RD = −(141µS )(820kΩ)= −116 Acc = 0 for RSS and ro = ∞ | vO = VO − (b) 2 ≤ 0.2V v1 GS Add 116.0 v1 = −3.80 + (0.02)= −2.64V 2 2 − VP = 0.2(0.14) = 28.0mV | v1 ≤ 56 mV based upon the small - signal limit Also vO ≤ −1 V for pinchoff. -1 ≤ −3.80 + 116.0 v1 → v1 = 48.3 mV | So, v1 ≤ 48.3 mV 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-23 15.38 +22 V RC RC 200 k Ω Q 200 k Ω Q 1 R1 2 k Ω + - RC Q 1 + - vic 1 vid R 1 +2R EE 2R EE 200 k Ω 402 k Ω 400 k Ω 2 R1 2kΩ -22 V Common-mode half circuit dc half-circuit Differential-mode half circuit (a) 150 22 − 0.7 = 52.6 µA | VCE = 22 − (200kΩ)IC − (−0.7) = 12.2 V 151 402kΩ 150(0.025V ) = 71.3kΩ Q − Point = (52.6µA, 12.2V ) for both transistors | rπ = 52.6µA (b) IC = α F IE = Acc = − Add = − β o RC rπ + (β o + 1)(R1 + 2REE ) =− 150(200kΩ) = −0.494 71.3kΩ + (151)402kΩ 150(200kΩ) β o RC =− = −80.4 rπ + (β o + 1)R1 71.3kΩ + (151)2kΩ Rid = 2[rπ + (β o + 1)R1 ] = 2[71.3kΩ + (151)2kΩ] = 747 kΩ Note also : Ric = 0.5[rπ + (β o + 1)(R1 + 2REE )] = 0.5[71.3kΩ + (151)(402kΩ)] = 30 MΩ and single - ended CMRR = 15-24 40.2 = 81.4, a paltry 38.2 dB 0.494 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.39 *Problem 15.39 – Figure P15.38 VCC 2 0 DC 22 VEE 1 0 DC -22 VIC 10 0 DC 0 V1 4 10 AC 0.5 V2 8 10 AC -0.5 RC1 2 5 200K RC2 2 9 200K Q1 5 4 3 NBJT Q2 9 8 7 NBJT RE1 3 6 2K RE2 7 6 2K REE 6 1 200K .MODEL NBJT NPN BF=150 .OP .AC LIN 1 1KHZ 1KHZ .PRINT AC IM(V1) IP(V1) VM(5,9) VP(5,9) .TF V(9) VIC .END Results : Add = VM(5,9) = −79.9 | Acc = −0.494 | Rid = 1 = 751 kΩ IM(V1) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-25 15.40 +V CC 100 k Ω 100 k Ω 100 k Ω 500 k Ω Q Q 1 + - EE -V v + v ic 1 2.5 k Ω id 2 100 µA I Q 1 REE 600 k Ω REE 600 k Ω EE dc half-circuit Common-mode half circuit (a) Differential-mode half circuit 100 (100µA)= 99.0 µA VCE = 20 −105 IC − (−0.7)= 10.8 V 101 100(0.025V ) Q − Po int = (99.0µA, 10.8V ) for both transistors | rπ = = 25.3kΩ 99.0 µA (b) I C = αF IE = Acc = − β o RL' 100kΩ =− = −0.165 rπ + (β o + 1)REE 25.3kΩ + 101(600kΩ) Add = − β o RL | RL = 100kΩ 500kΩ =83.3kΩ | R5 = 600kΩ 2.5kΩ =2.49kΩ rπ + (β o + 1)R5 Add = − 100(83.3kΩ) 25.3kΩ + 101(2.49kΩ) [ ] [ ⎛ 30.1 ⎞ Note : Single - ended CMRR = 0.5⎜ ⎟ = 91.2 and ⎝ 0.165 ⎠ [ ] [ ] Ric = 0.5 rπ + (β o + 1)R5 = 0.5 25.3kΩ + 101(600kΩ) = 30.3 MΩ 15-26 ] = −30.1 | Rid = 2 rπ + (β o + 1)R5 = 2 25.3kΩ + 101(2.49kΩ) = 554kΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.41 *Problem 15.41 – Figure P15.40 VCC 2 0 DC 20 VEE 1 0 DC -20 VIC 9 0 DC 0 V1 4 9 AC 0.5 V2 7 9 AC -0.5 RC1 2 5 100K RC2 2 8 100K RL 5 8 1MEG Q1 5 4 3 NBJT Q2 8 7 6 NBJT REE 3 6 5K IEE1 3 1 67.8U RE1 3 1 600K IEE2 6 1 67.8U RE2 6 1 600K .MODEL NBJT NPN BF=100 .OP .AC LIN 1 1KHZ 1KHZ .PRINT AC IM(V1) IP(V1) VM(5,8) VP(5,8) .TF V(8) VIC .END Results : Add = VM(5,8) = −30.0 | Acc = −0.165 | Rid = 1 = 555 kΩ IM(V1) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-27 15.42 +V CC R R D R D M M 1 Q D Q 1 + - v C = αF + - 2R 2 (b) I Q ic EE -V 1 1 I dc half-circuit M 1 1 v id 2 Differential-mode half circuit EE Common-mode half circuit EE 2 2x10−4 I EE 100 ⎛ 100µA ⎞ = VGS − (−4) → VGS = −3.29V ⎜ ⎟ = 49.5 µA | 49.5µA = 2 101 ⎝ 2 ⎠ 2 [ ] VCE = −VGS = 3.29V | VDS = 15 − 7.5x10 4 IC − VCE − (−0.7)= 8.70 V BJT Q − Points = (49.5µA, 3.29V ) | JFET Q − Points = (49.5µA, 8.70V ) rπ = 100(0.025V ) 49.5 µA = 50.5kΩ | Acc = − − β o RL rπ + (β o + 1)(2REE ) =− 100(75kΩ) 50.5kΩ + 101(1.2 MΩ) = −0.0619 Add = −g m1 RD = −40(49.5µA)(75kΩ)= −149 | Rid = 2rπ = 101kΩ ⎛ 149 ⎞ Note : Single - ended CMRR = 0.5⎜ ⎟ = 1200 or 61.6 dB and ⎝ 0.0619 ⎠ [ ] [ ] Ric = 0.5 rπ + (β o + 1)2REE = 0.5 50.5kΩ + 101(1.2 MΩ) = 60.6 MΩ (c) From (a) V CE 15-28 = −VGS = 3.29V | VBE = 0.7V | VCE ≥ VBE → Active − region operation ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.43 +V DD = 6 V I1 200 µA M1 M1 M3 M1 v1 v ic I2 100 µA M3 M3 v id 2 RD RD 30 k Ω 30 k Ω RD 30 k Ω - V SS = -6 V (a) Differential-mode half circuit Common-mode half circuit dc half-circuit (b) I D1 = I2 = 100µA | VGS1 = VTN + 2I D1 10−4 = 1+ 2 −3 = 1.447V | VGS1 − VTN = 0.447V Kn 10 I D3 = I1 − I D1 = 200µA −100µA = 100µA | VDS1 = −VGS 3 = 1+ 2 { [ VGS 3 − VTP = −0.632V | VDS 3 = − VS1 − VGS 3 − −6 + (30kΩ)I D3 10−4 = 1.632 V 5x10−4 ]}= −(−1.45 + 1.63 + 6 − 3)= −3.18V Both M1 and M3 are saturated. Q - points : M1 : (100µA, 1.63V ) M3 : (100µA, − 3.18V ) ( )( ) Add = −g m RD = − 2 10−4 10−3 (30kΩ) = −13.4 | For ro = ∞, Acc = 0 | Rid = ∞ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-29 15.44 (a) +V DD = 1.5 V I1 200 µA V S3 M1 -1.45 V +0.18 V M1 M3 100 µA M3 M3 V S1 I2 M1 -0.5 V v ic vid 2 R RD D RD 10 k Ω 10 k Ω 10 k Ω - V SS = 1.5 V (b) I Differential-mode half circuit Common-mode half circuit dc half-circuit D1 = I 2 = 100µA | VGS1 = VTN + 2I D1 10−4 = 1+ 2 −3 = 1.447V | VGS1 − VTN = 0.447V Kn 10 I D3 = I1 − I D1 = 200µA −100µA = 100µA | VDS1 = −VGS 3 = 1+ 2 { [ VGS 3 − VTP = −0.632V | VDS 3 = − VS1 − VGS 3 − −1.5 + (30kΩ)I D3 10−4 = 1.632 V 5x10−4 ]}= −(−1.45 + 1.63 + 1.5 − 3)= −1.32V These voltages can barely be supported by the 1.5- V negative power supply. VS1 = −VGS1 = −1.45V which is more negative than the -1.5 - V supply. Also, VS 2 = VS1 − VGS 3 = −1.45V + 1.63 = +0.18V , but for I D3 = 100µA, VD3 = −1.5 + 10−4 (10kΩ)= −0.5V. M3 is just beyond pinchoff, and current source I2 has a very small voltage across it. 15-30 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.45 (a) I C1 I1 100 ⎛ 50µA ⎞ = ⎜ ⎟ = 24.8 µA | VCE2 = 12 − VEB3 − (−VBE2 )= 12 V 2 101 ⎝ 2 ⎠ = αF 12V = 500 µA 24kΩ Q - points : (24.8 µA, 12V ) (24.8 µA, 12V ) (500 µA, 12V ) For VO = 0 → VEC3 = 12 V | IC 3 = (b) R C1 rπ 2 = rπ 3 = = 0.7V VEB3 0.7V = 28.2kΩ | RC 2 = = = 35.4kΩ 24.8µA IC 2 − I B3 24.8µA − 5µA 100(0.025V ) 24.8µA 100(0.025V ) 500µA = 101kΩ | ro2 = = 5kΩ | ro3 = ( 60 + 12 = 2.90 MΩ 24.8µA 60 + 12 = 144kΩ 500µA ) ( ) g m2 ro2 RC 2 rπ 3 g m3 ro3 R 2 40(24.8µA) Adm = 2.90 MΩ 35.4kΩ 5kΩ (40)(500µA) 144kΩ 24kΩ = 893 2 Rid = 2rπ 2 = 202 kΩ | (c) Rout = ro3 R = 20.6 kΩ Adm = ( (d ) R ic ≅ (β o + 1)ro2 2 ) = (101)2.90 MΩ = 147 MΩ 2 ( | (e) v 2 ) is the non - inverting input 15.46 vic ≥ −VEE + 0.75V + VBE1 = −12 + 0.7 + 0.75 = −10.6V vic ≤ VCC − VEB3 = 12 − 0.7 = 11.3V | −10.6 V ≤ vic ≤ 11.3 V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-31 15.47 Note that the parameters of the transistors and values of RC have been carefully adjusted to permit open-loop operation and achieve VO = 0. *Problem 15.47 - Two Stage Amplifier – Figure P15.45 VCC 1 0 DC 12 VEE 2 0 DC -12 RC1 1 5 28.2K RC2 1 7 33.9K Q1 5 4 3 NBJT Q2 7 6 3 NBJT I1 3 2 DC 50U Q3 8 7 1 PBJT R 8 2 24K V1 4 10 AC 0.5 V2 6 10 AC -0.5 VIC 10 0 DC 0 .MODEL NBJT NPN BF=100 VA=60 .MODEL PBJT PNP BF=100 VA=60 IS=0.288F .OPTIONS TNOM=17.2 .OP .AC LIN 1 1KHZ 1KHZ .TF V(8) VIC .PRINT AC VM(8) VP(8) IM(V1) IP(V1) .END Adm = VM(8) = 1030 | Acm = −6.07 x 10−3 | CMRRdB = 105 dB 1 Results: Rid = = 239 kΩ | Rout = 20.6 kΩ IM(V1) 15-32 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.48 IC1 = β F1 I B1 = β F1 I B [ [(β + 1)I ]≅ β ] IC 2 = β F 2 I B2 = β F 2 (β F1 + 1)I B ≅ β F1β F 2 I B IC = IC1 + IC 2 = β F 1 I B1 + β F 2 F1 B β I F1 F 2 B Assume β o2 = β o1 = β F 2 = β F1 g m1 = 40IC1 = β F1 I B rπ 1 = ro1 ≅ β o1 g m1 rπ 2 = β o2 g m2 VA V = A IC1 β F1 I B vbe1 = v be g m2 = 40IC2 ≅ β F 2β F1 I B g m2 = β o2 g m1 = β o1g m1 = β o1 β o1g m1 ro2 ≅ rπ 1 rπ 1 + (β o1 + 1)rπ 2 1 rπ 1 = β o1rπ 2 g m1 = VA VA ≅ IC2 β F1β F 2 I B ≅ vbe ro1 ≅ β o2ro2 = β o1ro2 β o1rπ 2 v v ≅ be → vbe2 ≅ be 2 β o1rπ 2 + (β o1 + 1)rπ 2 2 g m2 g vbe → Gm ≅ m2 2 2 RiB = rπ 1 + (β o1 + 1)rπ 2 = β o1rπ 2 + (β o1 + 1)rπ 2 ≅ 2β o1rπ 2 Gmvbe = g m1vbe1 + g m2vbe2 ≅ ⎡ (β o2 + 1) 1 ic = v ce2⎢ + ⎢ ro2 r 1+ g r r o1 m1 π 2 π 1 ⎣ RiC ≅ ro2 [ ( ( ( ro1 1+ g m1 rπ 2 rπ 1 β o2 ⎤ ⎡ β o2 ⎥≅v ⎢ 1 + ce2 ⎥ ⎢ ro2 r 1+ g r r o1 m1 π 2 π 1 ⎦ ⎣ )) )]≅ r [ [ ( ]= r ro1 1+ g m1 (rπ 2 ) o2 Note that βo = Gm RiB = β o1β o2 ≅ β o2 β o2 µf = Gm RiC = o2 2 ro1 β o2 ⎤ ⎥ ⎥ ⎦ )] 2 = ro2 2ro2 = ro2 3 µf 2 3 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-33 15.49 +V CC RC RC Q 4 Q3 Q vO Q 1 v1 2 I2 v2 I1 -V EE (a) I C1 I1 100 ⎛ 50µA ⎞ = ⎜ ⎟ = 24.8 µA | VCE 2 = VCC − VEB 3 − VEB 4 − (−VBE 2 )= 12 − 0.7 = 11.3 V 2 101 ⎝ 2 ⎠ = αF For VO = 0 → VEC 4 = 12 V and VEC 3 = 12 − 0.7 = 11.3 V | For balance, VCE1 = VCE 2 = 11.3 V ⎛ 1 ⎞ 12V I IC 4 + IC 3 = IC 4 + α F 3 I B 4 = IC 4 + α F 3 C 4 = IC 4 ⎜1+ | IC 4 = 495 µA | IC 3 = 4.95 µA ⎟= βF ⎝ β F + 1⎠ 24kΩ Q - points : (24.8 µA, 11.3V ) (24.8 µA, 11.3V ) (4.95 µA, −11.3V ) (495 µA, 12V ) (e) v 145 MΩ | (b) R C2 rπ 2 = = is the non - inverting input 2 VEB 3 + VEB 4 1.4V 1.4V = = 56.6kΩ | RC1 = = 56.5kΩ IC 2 − I B 3 24.8µA − 0.0495µA 24.8µA 100(0.025V ) 24.8µA = 101kΩ | ro2 = 100(0.025V ) 60 + 11.3 = 2.88 MΩ | rπ 3 = = 505kΩ 24.8µA 4.95µA 100(0.025V ) 60 + 11.3 60 + 11.3 = 14.4 MΩ | rπ 4 = = 5.05kΩ | ro 4 = = 144kΩ 4.95µA 495µA 495µA ⎛ g ⎞⎛ 2r ⎞ g g Darlington Adm = m2 ro2 RC 2 RinDarlington g mDarlington Rout R = m2 ro2 RC 2 2β orπ 4 ⎜ m 4 ⎟⎜ o 4 R⎟ 2 2 ⎝ 2 ⎠⎝ 3 ⎠ ro3 = ( Adm = ) ( ) ( ) 40(24.8µA) 2 40 495µA (2.88 MΩ 56.6kΩ 101kΩ)( )(2 )(96kΩ 24kΩ)= 9180 2ro4 R = 19.2 kΩ 3 (β + 1)r (101)2.88 MΩ = 145 MΩ | e v is the non - inverting input (d ) Ric ≅ o 2 o2 = () 2 2 Rid = 2rπ 2 = 202 kΩ | (c) Rout = 15-34 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.50 15V = 300µA | VC 2 = 15 − 2400I E 3 − VEB 3 = 15 − 0.729 − 0.7 = 13.6V 50kΩ ⎛ 200µA ⎞ 80 ⎛ 200µA ⎞ IC 3 300µA I C1 = I C 2 = α F ⎜ = = 3.75µA ⎟= ⎜ ⎟ = 98.8µA | I B 3 = βF 3 80 ⎝ 2 ⎠ 81 ⎝ 2 ⎠ (a) For V O = 0, IC 3 = VCE1 = VCE 2 = 13.6 − (−0.7)= 14.3V | VEC 3 = 15 − 2400I E 3 − VO = 14.3V Q - points : (98.8µA, 14.3V ) (98.8µA, 14.3V ) (300µA, 14.3V ) 80(0.025V ) 15 −13.6 V = 15.1kΩ | rπ 3 = = 6.67kΩ 0.3mA (98.8 − 3.75) µA RC = ⎛g ⎞ vc2 = −⎜ m1 ⎟ RC rπ 3 + (β o3 + 1)RE vid ⎝ 2 ⎠ ⎛ 40(98.8µA)⎞ ⎟ 15.1kΩ 6.67kΩ + 81(2.4kΩ) = −27.7 Av1 = −⎜⎜ ⎟ 2 ⎝ ⎠ [ [ (b) A v1 = [ ]] ( )] Av2 = 80(50kΩ) vo β o3 RL =− =− = −19.9 vc2 rπ 3 + (β o3 + 1)RE 6.67kΩ + 81(2.4kΩ) Av = vc2 vo = −27.7(−19.9)= 551 vid v c2 Rid = 2rπ 1 = 2 (c) R out (d ) R β o1VT IC1 =2 80(0.025V ) 98.8µA = 40.5kΩ | ro3 = 70 + 14.3 = 281kΩ 0.3mA ⎤ ⎡ ⎛ ⎞ 80(2.4kΩ) β o RE ⎥ =49.0kΩ = 50kΩ ro3 ⎜1+ ⎟ =50kΩ 281kΩ⎢1+ ⎝ RC + rπ 3 + RE ⎠ ⎢⎣ 15.1kΩ + 6.67kΩ + 2.4kΩ⎥⎦ ic = (β o1 + 1)ro1 2 = 81 ⎛ 70 + 14.3⎞ ⎜ ⎟ = 34.6 MΩ | 2 ⎝ 98.8µA ⎠ (e) v 2 is the non - inverting (+) input. 15.51 vic ≥ −VEE + 0.75V + VBE1 = −15 + 0.7 + 0.75 = −13.6V | vic ≤ VCC − I E 3 RE − VEB 3 ⎛ 81 ⎞⎛ 15V ⎞ From Prob. 15.92, I E 3 RE = ⎜ ⎟⎜ ⎟(2.4kΩ) = 0.729V ⎝ 80 ⎠⎝ 50kΩ ⎠ vic ≤ 15 − 0.729 − 0.7 = 13.6V | −13.6 V ≤ vic ≤ 13.6 V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-35 15.52 15V = 300µA VEC 3 = 15 − VO = 15 − 0 = 15V 50kΩ ⎛ 200µA ⎞ 80 ⎛ 200µA ⎞ IC 3 300µA I C1 = I C 2 = α F ⎜ = = 3.75µA ⎟= ⎜ ⎟ = 98.8µA I B 3 = βF 3 80 ⎝ 2 ⎠ 81 ⎝ 2 ⎠ (a) For V O = 0, IC 3 = VCE1 = VCE 2 = 15 − VEB 3 − (−VBE1 ) = 15.0V Q - points : (98.8µA, 15.0V ) (98.8µA, 15.0V ) (300µA, 15.0V ) RC 2 = rπ 2 = rπ 3 = V 0.7 0.7 V = 7.37kΩ | For balance, RC1 = = 7.09kΩ 98.8 µA (98.8 − 3.75) µA 80(0.025V ) 98.8µA 80(0.025V ) 0.3mA 15.53 For VO = 0, IC 3 = = 20.2kΩ | ro2 = 70V + 15V = 860kΩ 98.8µA = 6.67kΩ | ro3 = 70V + 15V = 283kΩ 0.3mA 15V I 300µA 81 = 300µA | I B3 = C 3 = = 3.75µA | I E3 = IC 3 = 304µA 50kΩ 80 80 βF 3 ⎛ 200µA ⎞ 80 ⎛ 200µA ⎞ 0.7V + I E3 RE 0.7V + (304µA)RE IC1 = IC 2 = α F ⎜ = ⎟= ⎜ ⎟ = 98.8µA | RC = IC1 − I B3 98.8µA − 3.75µA ⎝ 2 ⎠ 81 ⎝ 2 ⎠ VC2 = 15 − 2400I E3 − VEB 3 = 15 − 0.729 − 0.7 = 13.6V ( ) ( ) ( ) g m1 RC Rin3 = −20(98.8µA) RC Rin3 = -1.976x10-3 RC Rin3 | Rin3 = rπ 3 + (β o + 1)RE 2 ⎛ ⎞ β o RL β o RE Avt2 = − | RL = R ro3 ⎜1+ ⎟ | Av = Avt1 Avt2 rπ 3 + (β o + 1)RE ⎝ Rth + rπ 3 + RE ⎠ Avt1 = − Voltage Gain 1000 100 10 1 0 10000 20000 30000 Emitter Resistance 15-36 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.54 [ ] First, use our gain estimates to check feasibility of the design : Av ≅ 10(VCC + VEE ) = 32,400 2 There is plenty of margin available. Rout = R ro3 | 10−3 = 1 1 1 1 IC 3 1 1⎛ I R ⎞ = + = + = + ⎜ C3 ⎟ | VO = 0V Rout R ro3 R VA + VEC3 R R ⎝ VA + VEC3 ⎠ 100(0.025V ) 1⎛ 9 ⎞ 9 = 308Ω ⎜1+ ⎟ → R = 1.11 kΩ | IC3 = = 8.11mA | rπ 3 = 8.11mA R ⎝ 70 + 9 ⎠ R Avt2 = −g m3 Rout = −40(8.11mA)(1kΩ)= −324 | Avt1 = Avt1 = − ( Av 2000 = = −6.165 Avt2 −324 ) g m2 I Rr I R 0.7 RC rπ 3 = −20 C 2 C π 3 = −20 C 2 C ≅ −20 neglecting IB3 RC RC 2 RC + rπ 3 +1 +1 rπ 3 rπ 3 0.7 0.7V 0.7V 8.11mA = −6.165 → RC = 391Ω | IC1 = + I B3 = + = 1.87mA RC 391Ω 391Ω 100 +1 308 Selecting the closest 5% values : R = 1.1 kΩ , RC = 390 Ω , I1 = 3.74 mA −20 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-37 15.55 (a) For VO = 0, IC 3 = I2 = 300µA VC 2 = 15 − 2400I E 3 − VEB3 = 15 − 0.729 − 0.7 = 13.6V ⎛ 200µA ⎞ 80 ⎛ 200µA ⎞ IC 3 300µA IC1 = IC 2 = α F ⎜ = = 3.75µA ⎟= ⎜ ⎟ = 98.8µA | I B3 = βF 3 80 ⎝ 2 ⎠ 81 ⎝ 2 ⎠ VCE1 = VCE 2 = 13.6 − (−0.7)= 14.3V | VEC 3 = 15 − 2400I E3 − VO = 14.3V Q - points : (98.8µA, 14.3V ) (98.8µA, 14.3V ) (300µA, 14.3V ) RC 2 = 15 −13.6 V 15 −13.6 V = 14.7kΩ | For balance, RC1 = = 14.2kΩ 98.8 µA (98.8 − 3.75) µA 80(0.025V ) rπ 3 = 0.3mA = 6.67kΩ | ro2 = 80V = 810kΩ 98.8µA ⎛g ⎞ v c2 = −⎜ m1 ⎟ RC 2ro2 rπ 3 + (β o3 + 1)RE v id ⎝ 2 ⎠ ⎛ 40(98.8µA)⎞ ⎟ 15.1kΩ 1.62 MΩ 6.67kΩ + 81(2.4kΩ) = −27.5 Avt1 = −⎜⎜ ⎟ 2 ⎝ ⎠ ⎛ ⎞ vo β o3 RL β o RE 70 + 14.3 ⎜ ⎟ | ro3 = Avt2 = =− | RL = ro3⎜1+ = 281kΩ ⎟ 300µA vc2 rπ 3 + (β o3 + 1)RE ⎝ RC 2ro2 + rπ 3 + RE ⎠ ⎛ ⎞ 80(2.4kΩ) 80(2.53MΩ) ⎟ = 2.53MΩ | Avt2 = − = −1010 RL = 281kΩ⎜⎜1+ ⎟ 6.67kΩ + 81(2.4kΩ) ⎝ 14.8kΩ + 6.67kΩ + 2.4kΩ ⎠ (b) A vt1 { = ]} [ [ )] ( Av = Avt1 Avt2 = −27.5(−1010)= 27800 | Rid = 2rπ 1 = 2 β o1VT IC1 =2 80(0.025V ) 98.8µA = 40.5kΩ Rout = RL = 2.51 MΩ 15.56 The amplifier has an offset voltage of approximately 3.92 mV. Use this value to force the output to nearly zero. A transfer function analysis then yields Av = +28,627 Rout = 2.868 MΩ Rin = +50.051 kΩ These values are similar to the hand calculations in Prob. 15.55. Rin and Rout are larger because the hand calculations did not adjust the value of current gain based upon the Early voltage. 15.57 ⎛ 200µA ⎞ 100 ⎛ 200µA ⎞ IC1 = IC 2 = α F ⎜ ⎟= ⎜ ⎟ = 99.0µA | VCE1 = VCE2 = 15 − VEB 3 − (−VBE1 ) = 15V ⎝ 2 ⎠ 101 ⎝ 2 ⎠ For VO = 0, IC 3 = I2 = 300µA | VEC3 = 15 − VO = 15V Q - points : (99.0µA, 15.0V ) (99.0µA, 15.0V ) (300µA, 15.0V ) 15-38 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.58 { ]} [ g m1 RC 2ro2 rπ 3 + (β o3 + 1)RE 2 ⎡ ⎤ β o Rout βo β R o E ⎥ Avt2 = − =− ro3⎢1+ rπ 3 + (β o + 1)RE rπ 3 + (β o + 1)RE ⎢⎣ RC 2ro2 + rπ 3 + RE ⎥⎦ Av = Avt1 Avt2 | Avt1 = − ( ) I1 80 200µA = = 98.8µA | For VO = 0, IC3 = I2 = 300µA 2 81 2 300µA 81 = = 3.75µA | I E3 = IC 3 = 303.8µA | VEC 3 = 15 − I E 3 RE 80 80 IC1 = IC 2 = α F IC3 I B3 = βF 3 RC2 = rπ 3 = 0.7V + I E3 RE 0.7V + (303.8µA)RE = IC1 − I B3 98.8µA − 3.75µA 80(0.025V ) 300µA = 6.67kΩ | ro3 = g m1 = 40(98.8µA)= 3.95mS | ro2 = 70 + 15 − (303.8µA)RE 300µA 70 + 14.3 − (303.8µA)RE 98.8µA Voltage Gain 30000 20000 10000 0 0 10000 20000 30000 40000 Emitter Resistance ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-39 15.59 ( ) 2 2.5x10-4 500µA 2I D2 (a) I D2 = 2 = 250µA | VS = VSG = −VTP + K = 1+ 5x10-3 = 1.32V p VD = −15 + 0.7 = −14.3V | VDS = VD − VS = −14.3 −1.32 = −15.6V | Q - pt : (250µA, −15.6V ) IC3 = 500µA | VCE 3 = VC 3 - VE3 = 0 - (-15) = 15V | Q - pt : (500µA, 15V ) VBE = I D2 − I B3 RD = (b) g 0.7V = 2.87kΩ 500µA 250µA − 80 = 2(0.005)(0.00025) = 1.58x10−3 S | rπ 3 = 80(0.025V ) = 4kΩ 0.5mA v v g 1.58mS Av = d2 o = Avt1 Avt2 | Avt1 = − m2 RD rπ 3 = − 2.87kΩ 4kΩ = −1.30 2 vid v d2 2 ⎛ 75V + 15V ⎞ Avt2 = −g m3 ro3 R2 = −40(0.5mA)⎜ 2 MΩ⎟ = −0.02 180kΩ 2 MΩ = −3300 ⎝ 0.5mA ⎠ m2 ( ( ) ) ( ) ( ) Av = −1.30(−3300) = 4300 | Rin = ∞ | Rout = ro3 R2 = 180kΩ 2 MΩ = 165kΩ (c) v 2 15-40 is the non - inverting (+) input (d ) v 1 is the inverting (-) input ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.60 Note that the parameters of the transistors and values of RD have been carefully adjusted to permit open-loop operation and achieve VO = 0. *Problem 15.60 – Figure P15.59 VCC 7 0 DC 15 VEE 8 0 DC -15 V1 1 9 AC 0.5 V2 3 9 AC -0.5 VIC 9 0 DC 0 I1 7 2 DC 493.2U R1 7 2 2MEG M1 4 1 2 2 PFET M2 5 3 2 2 PFET RD1 4 8 2.863K RD2 5 8 2.863K Q3 6 5 8 NBJT I2 7 6 DC 492.5U R2 7 6 2MEG .MODEL PFET PMOS KP=5M VTO=-1 .MODEL NBJT NPN BF=80 VA=75 IS=0.2881FA .OP .AC LIN 1 1000 1000 .TF V(6) VIC .PRINT AC IM(V1) IP(V1) VM(6) VP(6) .OPTIONS TNOM=17.2 .END Adm = VM(6) = 4630 | Acm = −1.46 | CMRRdB = 70.0 dB 1 Results: R = = ∞ | Rout = 164 kΩ id IM(V1) 15.61 v v g Av = d2 o = Avt1 Avt2 | Avt1 = − m2 RD rπ 3 vid v d2 2 ( )| IC3 = 100µA | rπ 3 = 80(0.025V ) 100µA = 20kΩ 500µA = 250µA | g m2 = 2(0.005)(0.00025) = 1.58x10−3 S 2 VBE 0.7V 1.58mS RD = = = 2.81kΩ | Avt1 = − 2.81kΩ 20kΩ = −1.95 100µA I D2 − I B3 2 250µA − 80 ⎛ 75V + 5V ⎞ Avt2 = −g m3 ro3 R2 = −40(100µA)⎜ 10 MΩ⎟ = −0.02 800kΩ 10 MΩ = −2960 ⎝ 100µA ⎠ I D2 = ( ( ) ( ) ) Av = −1.95(−2960)= 5770 15.62 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-41 VGS 2 = VTP − 2I D 5x10 4 = −1− = −1.316V KP 5x103 For PMOS active region : VDS 2 ≤ VGS 2 − VTP = −0.316V vic ≥ −VEE + VBE3 − VDS 2 + VGS 2 = −15 + 0.7 + 0.316 −1.316 = −15.3V vic ≤ VCC − 0.75 + VGS 2 = 15 − 0.75 −1.316 = 12.9V | −15.3 V ≤ vic ≤ 12.9 V 15.63 ( ) 2 2.5x10-4 500µA 2I D2 (a) I D2 = 2 = 250µA | VS = −VGS = −VTP + K = −1+ 5x10-3 = 1.32V p VD = −5 + 0.7 + 0.7 = −3.6V | VDS = VD − VS = −3.6 −1.32 = −4.92V | Q - pt : (250µA, - 4.92V ) IC3 + IC 4 = 500µA | IC3 + β F I E3 = (β F + 2)IC 3 = 500µA → IC 3 = 6.10µA | IC 4 = 494µA For VO = 0, VCE 4 = 5V and VCE3 = 5 - 0.7 = 4.30V Q - pts : (250µA, - 4.92V ) (250µA, - 4.92V ) (6.10µA, 4.30V ) (494µA, 5.00V ) VBE3 + VBE 4 = I D2 − I B 3 1.4V = 5.60kΩ | Based upon results for the Darlington 6.10µA 250µA − 80 80(0.025V ) g circuit in Prob. 15.48 : Avt1 = m1 RD 2rπ 3 | rπ 3 = = 328kΩ 2 6.10µA 1.58mS g m1 = 2(0.005)(0.00025) = 1.58mS | Avt1 = − 5.60kΩ 656kΩ = −4.39 2 ⎤ ⎞ 40(494µA)⎡2 ⎛ 75V + 5V ⎞ g ⎛2 Avt2 = − m4 ⎜ ro4 R2 ⎟ = − ⎢ ⎜ ⎟ 1MΩ⎥ = −9.88mS 108kΩ 1MΩ = −963 2 ⎝3 2 ⎠ ⎣ 3 ⎝ 494µA ⎠ ⎦ ⎛2 ⎞ Av = −4.39(−963)= 4230 | Rid = ∞ | Rout = ⎜ ro4 ⎟ R2 = 108kΩ 1MΩ = 97.5 kΩ ⎝3 ⎠ RD = ( ) ( ) ( 15.64 *Problem 15.64 – Figure P15.63 *Vos (the dc value of V2) has been carefully adjusted to set Vo ≈ 0 VCC 8 0 DC 5 VEE 9 0 DC -5 V1 1 10 AC 0.5 V2 3 10 DC 1.21M AC -0.5 VIC 10 0 DC 0 I1 8 2 DC 496.3U R1 8 2 1MEG M1 4 1 2 2 PFET M2 5 3 2 2 PFET RD1 4 9 5.6K RD2 5 9 5.6K 15-42 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ) Q3 7 5 6 NBJT Q4 7 6 9 NBJT I2 8 7 DC 495U R2 8 7 1MEG .OP .MODEL PFET PMOS KP=5M VTO=-1 .MODEL NBJT NPN BF=80 VA=75 .AC LIN 1 1000 1000 .TF V(7) VIC .PRINT AC IM(V1) IP(V1) VM(7) VP(7) .END Adm = VM(7) = 4080 | Acm = −2.58 | CMRRdB = 64.0 dB 1 Results: R = = ∞ | Rout = 96.2 kΩ id IM(V1) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-43 15.65 +V R C R CC C Q 3 v 1 v Q Q 1 Q4 2 2 Q5 vO = 0 I I1 R I 2 L 3 2kΩ -V EE The new output stage can be treated as an improved single transistor using the results from Prob. 15.48. Using the results from Ex. 15.5: Rin4-5 = 2β orπ 4 + β o2 RL = 2(100)(505Ω)+ 1002 (2kΩ)= 20.1MΩ | Av2 becomes ( ) ( ) Av2 = −g m3 ro3 Rin4−5 = −22mS 161kΩ 20.1MΩ = −3510 | The gain of the g m4 RL 40 4.95x10−3 (2kΩ) g m4 RL 2 emitter follower becomes Av3 ≅ = = 0 = 0.995 g m4 RL 2 + g m4 RL 2 + 40 4.95x10−3 (2kΩ) 1+ 2 Av = −3.50(−3510)(0.995)= 12200. ( ( CMRR and Rid do not change : CMRR = 63.5 dB and Rid = 101 kΩ Rout = 15-44 2 r 2 161kΩ + o32 = + = 26.2 Ω −3 g m4 β o 40 4.95x10 10 4 ( ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ) ) 15.66 +V R C R CC C Q 3 v 1 v Q Q 1 Q4 2 2 Q5 vO = 0 I I1 R I 2 L 3 2kΩ -V EE The new output stage can be treated as an improved single transistor using the equation set from prob. 15.48 and the results from Ex. 15.4 Rin4-5 = 2β orπ 4 + β o2 RL = 2(100)(505Ω)+ 1002 (2kΩ) = 20.1MΩ | Av2 becomes ( ) ( ) Av2 = −g m3 ro3 Rin4−5 = −22mS 161kΩ 20.1MΩ = −3510 | The gain of the g m4 RL 40 4.95x10−3 (2kΩ) g m4 RL 2 emitter follower becomes Av3 ≅ = = 0 = 0.995 g m4 RL 2 + g m4 RL 2 + 40 4.95x10−3 (2kΩ) 1+ 2 Av = −3.50(−3510)(0.995)= 12200. ( ( ) ) CMRR and Rid do not change : CMRR = 63.5 dB and Rid = 101 kΩ Rout = 2 r 2 161kΩ + o32 = + = 26.2 Ω −3 g m4 β o 40 4.95x10 10 4 ( ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-45 15.67 I1 100 ⎛ 100µA ⎞ = ⎜ ⎟ = 49.5µA | VEC 2 = +0.7V − (−15V + 0.7V )= 15.0V 2 101 ⎝ 2 ⎠ ⎛100 ⎞ For VO = 0, IC 4 = α F I3 = ⎜ ⎟1.00mA = 990µA | VEC 4 = 0 − (−15V )= 15.0V ⎝ 101 ⎠ 1mA IC3 = I2 + I B 4 = 350µA + = 360µA | VCE3 = VO − 0.7V − (−15) = 14.3 101 Q − pts : (49.5µA, 15.0V ) (49.5µA, 15.0V ) (360µA, 14.3V ) (990µA, 15.0V ) (a) I C1 (b) R C = IC 2 = α F = 0.7V 0.7V = = 15.3kΩ IC 2 − I B3 (49.5 − 3.60)µA 100(0.025V ) 50V = 1.01MΩ | rπ 3 = = 6.94kΩ 49.5µA 360µA 50 + 14.3 g g ro3 = = 179kΩ | Av = Avt1 Avt2 Avt3 = m1 RC 2ro2 rπ 3 (g m3ro3 )() 1 = m1 RC 2ro2 rπ 3 µ f 3 2 2 360µA ro2 = ( ) ( 40(49.5µA) Av = (15.3kΩ 2.02 MΩ 6.94kΩ)(40)(64.3)= 12100 2 Rid = 2rπ 1 = 2 (c) R out (d ) R ic 15-46 = = 100(0.025V ) 49.5µA ro3 + rπ 4 β o4 + 1 (β o1 | rπ 4 = + 1)ro1 2 = 101 kΩ 100(0.025V ) | ro1 = 990µA = 2.53kΩ | Rout = 179kΩ + 2.53kΩ = 1.80 kΩ 101 101(1.31MΩ) 50V + 15V 1.31MΩ | Ric = = 66.3 MΩ (e) v2 49.5µA 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ) 15.68 *Problem 15.68 – Figure P15.67 *RC and Vos (see V2) have been carefully adjusted to set Vo ≈ 0 VCC 7 0 DC 15 VEE 8 0 DC -15 V1 1 9 DC 0.117M AC 0.5 V2 3 9 AC -0.5 VIC 9 0 DC 0 I1 7 2 DC 100U Q1 4 1 2 PBJT Q2 5 3 2 PBJT RC1 4 8 15.8K RC2 5 8 15.8K Q3 6 5 8 NBJT I2 7 6 DC 350U Q4 8 6 10 PBJT I3 7 10 DC 1M .MODEL PBJT PNP BF=100 VA=50 .MODEL NBJT NPN BF=100 VA=50 .NODESET V(10)=0 .OP .AC LIN 1 1000 1000 .TF V(10) VIC .PRINT AC IM(V1) IP(V1) VM(10) VP(10) .END Adm = VM(10) = 13800 | Acm = −0.0804 | CMRRdB = 105 dB 1 Results: R = = 133 kΩ | Rout = 1.37 kΩ id IM(V1) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-47 15.69 (a) Working backwards from the output :V = V − V = 12 − 0 = 12.0V | I = I = 5.00mA 2(0.005) 2I V =V + = 0.75 + = 2.16V | V = −(V − V )= −(12 − 2.16)= −9.84V K 0.005 DS 4 D4 GS 4 DD DS 3 TN D4 O DD 3 GS 4 n I D3 = I2 = 2.00mA | VGS 3 = VTP − 2(0.002) 2I D 4 = −0.75V − = −2.16V Kn 0.002 VD2 = VDD + VGS 3 = 12V − 2.16V = 9.84V | I D1 = I D2 = ( 2 2.5x10−4 ) = 1.07V I1 = 250µA 2 | VDS1 = VDS 2 = 9.84V − (−1.07V )= 10.9V 5x10 Q − pts : (250µA,10.9V) (250µA,10.9V) (2.00mA,-9.84V) (5.00mA,12.0V) VGS 2 = 0.75V + (b) A dm = −3 µf 4 g r g m1 g 2.16V RD (g m3ro3 ) m4 o4 = m1 RD µ f 3 | RD = = 8.64kΩ 2 1+ g m4ro4 2 1+ µ f 4 0.25mA ( g m1 = 2 5x10−3 )( Adm = 15-48 )[ ] ( )( )[ ] 2(5x10 )(5x10 )[1+ 0.02(12)] = 7.87mS g m3 = 2 2x10−3 g m4 = 1 + 9.84 −4 0.015 2.5x10 1+ 0.02(10.9) = 1.75mS | ro3 = = 38.3kΩ 2mA 1 + 12 2x10−3 1+ 0.015(9.84) = 3.03mS | ro4 = 0.02 = 12.4kΩ 5mA −3 −3 | µ f 3 = g m3ro3 = 116 | µ f 4 = 97.6 1.75ms 1 97.6 8.64kΩ)(116) = 868 | Rid = ∞ | Rout = = 127Ω ( 2 g m4 1+ 97.6 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.70 *Problem 15.70 – Figure P15.69 *The values of RD have been adjusted to bring the offset voltage to ≈ 0 VCC 8 0 DC 12 VEE 9 0 DC -12 V1 1 10 AC 1 V2 3 10 AC 1 VIC 10 0 DC 0 I1 2 9 DC 500U M1 4 1 2 2 NFET M2 5 3 2 2 NFET RD1 8 4 8.28K RD2 8 5 8.28K M3 6 5 8 8 PFET M4 8 6 7 7 NFET I2 6 9 DC 2M I3 7 9 DC 5M .MODEL PFET PMOS KP=2M VTO=-0.75 LAMBDA=0.015 .MODEL NFET NMOS KP=5M VTO=0.75 LAMBDA=0.02 .OP .AC LIN 1 1000 1000 .TF V(7) VIC .PRINT AC VM(7) VP(7) IM(V1) IP(V1) .END Adm = VM(7) = 802 | Acm = −4.74 x10 -7 ≅ 0 | CMRRdB = ∞ 1 Results: Rid = = 10 30 ≅ ∞ | Rout = 126 Ω IM(V1) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-49 15.71 (a) Working backwards from the output :VDS 4 = −(VO − VSS )= 0 + (−5)= −5.00V I D 4 = I3 = 2.00mA | VGS 4 = VTP − 2(0.002) 2I D 4 = −0.7 − = −2.11V Kp 0.002 VDS 3 = VO + VGS 4 − (−VSS ) = 0 − 2.11+ 5 = 2.89V ( ) 2 5x10−4 2I D 4 = 0.75V + = 1.15V I D3 = I2 = 500µA | VGS 3 = VTN + Kn 5x10−3 VD2 = −VSS + VGS 3 = −5 + 1.15V = −3.85V | I D1 = I D2 = ( 2 3x10−4 ) = −1.25V I1 = 300µA 2 [ ] | VDS 2 = VDS 2 = − 1.25 − (3.85) = −5.10V 2x10 Q − pts : (300µA,−5.10V ) (300µA,−5.10V ) (500µA,2.89V ) (2.00mA,5.00V ) VGS1 = VGS 2 = −0.7V − (b) A dm = −3 µf 4 g m1 g 1.15V g r RD (g m3ro3 ) m4 o4 = m1 RD µ f 3 | RD = = 3.83kΩ 2 1+ g m4ro4 2 1+ µ f 4 0.3mA ( )( g m1 = 2 2x10−3 3x10−4 )[ Adm = ] ( )( )[ ] 2(2x10 )(2x10 )[1+ 0.015(15)] = 2.93mS g m3 = 2 5x10−3 5x10−4 g m4 = 1 + 2.89 0.02 1+ 0.015(5.10) = 1.14mS | ro3 = = 106kΩ 0.5mA 1 + 5.00 1+ 0.02(2.89) = 2.30mS | ro4 = 0.015 = 35.8kΩ 2mA −3 −3 | µ f 3 = g m3ro3 = 244 | µ f 4 = 105 1.14ms 1 105 3.83kΩ)(244) = 528 | Rid = ∞ | Rout = = 341Ω ( 2 g m4 1+ 105 15.72 The amplifier has an offset voltage of approximately –6.69 mV. This value is used to force the output to nearly zero. A transfer function analysis then yields Av = +517 Rout = 339 Ω Rin = +1.00 x 1020 Ω These values are similar to the hand calculations in Prob. 15.71. 15-50 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.73 (a) Working backwards from the output :VDS 4 = −(VO − VSS )= 0 + (−5)= −5.00V I D 4 = I3 = 2.00mA | VGS 4 = VTP − 2(0.002) 2I D 4 = −0.7 − = −2.11V Kp 0.002 VCE3 = VO + VGS 4 − (−VSS )= 0 − 2.11+ 5 = 2.89V IC3 = I2 = 500µA | VD2 = −VSS + VBE3 = −5 + 0.7V = −4.30V | I D1 = I D2 = ( 2 3x10−4 ) = −1.25V [ I1 = 300µA 2 ] | VDS1 = VDS 2 = − 1.25 − (−4.30) = −5.55V 2x10 Q − pts : (300µA,−5.55V ) (300µA,−5.55V ) (500µA,2.89V ) (2.00mA,5.00V ) VGS1 = VGS 2 = −0.7V − (b) A dm = RD = −3 ⎛ g r ⎞ g µf 4 g m1 RD rπ 3 (g m3ro3 )⎜ m4 o4 ⎟ = m1 RD rπ 3 µ f 3 2 1+ µ f 4 ⎝ 1+ g m4ro4 ⎠ 2 ( ) ( ) 150(0.025V ) 0.7V = 2.33kΩ | rπ 3 = = 7.53kΩ 0.3mA 500µA 1 + 2.89 g m1 = 2 2x10−3 3x10−4 1+ 0.015(5.10) = 1.14mS | ro3 = 0.02 = 106kΩ 0.5mA 1 + 5.00 = 35.8kΩ g m4 = 2 2x10−3 2x10−3 1+ 0.015(15) = 2.93mS | ro4 = 0.015 2mA µ f 3 = g m3ro3 = 40(70) = 2800 | µ f 4 = 105 Adm = ( )( )[ ( )( )[ ( ] ] ) 1.14ms 1 105 2.33kΩ 7.53kΩ (2800) = 2810 | Rid = ∞ | Rout = = 341Ω 2 g m4 1+ 105 15.74 The amplifier has an offset voltage of approximately 48.69 mV. This value is used to force the output to nearly zero. A transfer function analysis then yields Av = +2810 Rout = 339 Ω Rin = +1.00 x 1020 Ω These values are similar to the hand calculations in Prob. 15.73 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-51 15.75 (a) Working backwards from the output with VO = 0 : VDS 4 = VCC − VO = 5 − 0 = 5V ID 4 = I3 = 2mA | VGS 4 = VTN + 2(0.002) 2ID 4 = 0.7 + = 1.59V | IC 3 = I2 = 500µA Kn 0.005 VEC 3 = 5 − VGS 4 = 5 −1.59 = 3.41V | VCE 2 = 5 − VEB 3 − (−VBE 2 ) = 5 − 0.7 + 0.7 = 5.00V IC1 = IC 2 = α F VEB 3 0.7V I1 100 200µA = = 99.0µA | RC = = = 7.45kΩ 2 101 2 IC 2 − IB 3 (99.0 − 5.00)µA VCE1 = 5 − IC1RC − (−VBE 2 ) = 5 − 99.0µA(7.45kΩ) + 0.7 = 4.96V Q = pts : (99.0µA, 4.96V ) (99.0µA, 5.00V ) (500µA, 3.41V ) (2.00mA, 5.00V ) (b) Using current division at the collector of Q2 : Adm = rπ 3 = ⎛ gm 4 RL ⎞ gm1 gm1 ⎛ RC ⎞ g R RC rπ 3 )µ f 3 m 4 L ( ⎜ ⎟β o3 ro3 ⎜ ⎟= 2 ⎝ RC + rπ 3 ⎠ 1+ gm 4 RL ⎝ 1+ gm 4 RL ⎠ 2 100(0.025V ) = 5.00kΩ | gm 4 = 2(0.005)(0.002) = 4.47mS 500µA Adm = 40(99.0µA) 4.47mS (2kΩ) 7.45kΩ 5.00kΩ)(40)(50 + 3.41) = 11400 ( 2 1+ 4.47mS (2kΩ) Rid = 2rπ 1 = 2 100(0.025V ) 1 = 50.5 kΩ | Rout = = 224 Ω gm 4 99.0µA (c) *Problem 15.75 – Figure P15.75 *The values of RC have been adjusted to set Vo ≈ 0. VCC 8 0 DC 5 VEE 9 0 DC -5 VIC 10 0 DC 0 V1 1 10 AC 0.5 V2 3 10 AC -0.5 I1 2 9 DC 200U Q1 4 1 2 NBJT Q2 5 3 2 NBJT RC1 8 4 8.00K RC2 8 5 8.00K Q3 6 5 8 PBJT I2 6 9 DC 500U M4 8 6 7 7 NFET I3 7 9 DC 2M RL 7 0 2K .MODEL NBJT NPN BF=100 VA=50 .MODEL PBJT PNP BF=100 VA=50 .MODEl NFET NMOS KP=5M VTO=0.70 .OP .AC LIN 1 2KHZ 2KHZ 15-52 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 .PRINT AC VM(7) VP(7) IM(V1) IP(V1) .TF V(7) VIC .END Adm = VM(7) = 11200 | Acm = −0.0957 | CMRRdB = 101 dB 1 Results: R = = 56.4 kΩ ≅ ∞ | Rout = 201 Ω id IM(V1) 15.76 (a) I C1 I1 100 10µA I 50 50µA = = 4.95 µA | IC 3 = IC 4 = α F 2 = = 24.5 µA 2 101 2 2 51 2 ⎛ 24.5 µA ⎞ − (IC 2 − I B3 )RC − (−VBE 2 )= 3V − ⎜4.95µA − ⎟300kΩ − (−0.7)= 2.36V 50 ⎠ ⎝ = IC2 = α F VCE2 = VCC 50 (250µA)= 245µA | VEC 5 = 3.00 V | VC 4 = −0.7V 51 ⎛ 24.5 µA ⎞ VC1 = 3 − ⎜ 4.95µA − ⎟300kΩ = 1.66V | VEC 3 = VEC 4 = 1.66 + 0.7 − (−0.7)= 3.06V 50 ⎠ ⎝ For VO = 0 : IC5 = α F I3 Q - pts : (4.95µA,2.36V ) (4.95µA,2.36V ) (24.5µA,3.06V ) (24.5µA,3.06V ) (245µA,3.00V ) (b) A dm rπ 3 = ro1 = ( = g m1 RC1 rπ 3 ro1 50(0.025V ) 24.5µA ) ( [ g m3 RC 2 2ro4 rπ 5 + (β o5 + 1)RL 2 = 51.0kΩ | ro4 = ⎛ (β + 1)R ⎞ o5 L ⎟ ⎜ ⎜r + β +1 R ⎟ ⎝ π 5 ( o5 ) L ⎠ ]) 50(0.025V ) 70 = 2.86 MΩ | rπ 5 = = 5.10kΩ 245µA 24.5µA (β o5 + 1)RL = 51(5kΩ) = 0.980 50 = 10.1MΩ | 4.95µA rπ 5 + (β o5 + 1)RL 5.10kΩ + 51(5kΩ) ( ) Adm = 40(4.95µA) 300kΩ 51.0kΩ 10.1MΩ • (40)(24.5µA) 78kΩ 5.72 MΩ ( 2 Rid = 2rπ 1 = 2 100(0.025V ) 4.95µA = 1.01 MΩ | Rout = [5.10kΩ + 51(5kΩ)])0.980 = 235 RC 2 + rπ 5 78kΩ 5.72 MΩ + 5.10kΩ = = 1.59 kΩ β o5 + 1 51 (c) v is the non - inverting input - v is the inverting input (d) A = (10V )(10V )= 30 = 900 | r << R is substantailly reducing the gain A B 2 v CC CC π3 C Also, the input resistance of the emitter follower is low, Rin5 = 107kΩ ≈ RC 2 , and is reducing the gain by an additional factor of almost 2. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-53 15.77 I1 100 ⎛ 100µA ⎞ I2 50 ⎛ 200µA ⎞ = ⎜ ⎟ = 49.5 µA | IC 3 = IC 4 = α F = ⎜ ⎟ = 98.0 µA 2 101 ⎝ 2 ⎠ 2 51 ⎝ 2 ⎠ ⎛ 98.0 µA ⎞ VCE2 = VCC − (IC 2 − I B3 )RC − (−VBE2 )= 18V − ⎜49.5µA − ⎟120kΩ − (−0.7)= 13.0V 50 ⎠ ⎝ 50 For VO = 0 : IC 5 = α F I3 (750µA) = 735µA | VEC 4 = 18 V | VC 4 = −0.7V 51 ⎛ 98.0 µA ⎞ VC1 = 18 − ⎜ 49.5µA − ⎟120kΩ = 12.3V | VEC 3 = VEC 4 = 12.3 + 0.7 − (−0.7) = 13.7V 50 ⎠ ⎝ (a) I C1 = IC 2 = α F Q - pts : (49.5µA,13.0V ) (49.5µA,13.0V ) (98.0µA,13.7V ) (98.0µA,13.7V ) (735µA,18.0V ) ( (b) A dm = g m1 RC1 rπ 3 ro2 rπ 3 = ro2 = 50(0.025V ) 98.0µA (β o5 + 1)RL g m3 RC2 2ro4 rπ 5 + (β o5 + 1)RL 2 rπ 5 + (β o5 + 1)RL ) ( ]) [ = 12.8kΩ | ro4 = 50(0.025V ) 70V = 714kΩ | rπ 5 = = 1.70kΩ 98.0µA 735µA (β o5 + 1)RL = 51(2kΩ) = 0.984 50V = 1.01MΩ | 49.5µA rπ 5 + (β o5 + 1)RL 1.70kΩ + 51(2kΩ) ( ) Adm = 40(49.5µA) 120kΩ 12.8kΩ 1.01MΩ • (40)(98.0µA) 170kΩ 1.43MΩ Rid = 2rπ 1 = 2 2 100(0.025V ) 49.5µA (c) For positive v IC ( = 101 kΩ | Rout = [1.70kΩ + 51(2kΩ)])0.984 = 2700 RC 2 + rπ 5 170 + 1.70 = kΩ = 3.37 kΩ 51 β o5 + 1 , vIC ≤ VC1 = 12.3V | For negative v IC , the characteristics of I1 will deterimine vIC . For the ideal current source, the negative limit of v IC is not defined. (d) The actual voltage at the collector of Q 4 would be ⎛ 735µA ⎞ VC 4 = −18V + (IC 4 + I B 5 )RC2 = −18V + ⎜ 98.0µA + ⎟170kΩ = 1.16V and VO = +1.86V 50 ⎠ ⎝ should be - 0.7V. The value of offset voltage required to bring the output back to zero is ∆V 1.86V VOS = O = = 0.689 mV. 2700 Adm 15-54 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.78 (a) I I1 100 ⎛ 200µA ⎞ 100 ⎛ 12V ⎞ = ⎜ ⎟ = 99.0µA | For VO = 0 : IC 3 = α F I E3 = ⎜ ⎟ = 990µA 2 101 ⎝ 2 ⎠ 101 ⎝ 12kΩ ⎠ C1 = I C 2 = α F VCE3 = 12V − 0V = 12.0V | VCE 2 = +0.7 − (−0.7)= 1.4V RC = 12V − 0.7V 0.7V = = 104 kΩ | VCE1 = 12 − 99.0µA(104kΩ)− (−0.7) = 2.40V IC 2 + I B 3 (99.0 + 9.90)µA Q - points : (99.0µA,2,40V ) (99.0µA,1.40V ) (990µA,12V ) ( [ g (b) Adm = 2m2 RC 2ro2 rπ 3 + (β o3 + 1)R ro2 = ⎛ (β + 1)R ⎞ o3 ⎜ ⎟ ⎜r + β +1 R⎟ ⎝ π 3 ( o3 ) ⎠ ]) 100(0.025V ) 70V = 707kΩ | rπ 3 = = 2.53kΩ 990µA 99.0µA Adm = 40(99.0µA) 2 Rid = 2rπ 1 = 2 (104kΩ 1.41MΩ [2.53kΩ + (101)12kΩ])2.53kΩ( +)(101)12kΩ = 177 101 12kΩ 100(0.025V ) 99.0µA 15.79 = 50.5 kΩ | Rout = RC 2ro2 + rπ 3 β o3 + 1 = 96.9kΩ + 2.53kΩ = 984 Ω 101 100(0.025V ) = 16.7µA. For VO = 0, VC1 = 0.7V 300kΩ 12 − 0.7 11.3V 11.3V R +r 677kΩ ≅ = = 677kΩ | Rout ≅ C π 3 ≥ = 6.7kΩ RC = IC1 + I B3 IC1 16.7µA 101 β o3 + 1 300kΩ = 2rπ 1 → IC1 = 2 The Rout specification cannot be meet if the Rid specification is met and vice - versa. Either Rid must be reduced or Rout must be increased, or both must be changed. 15.80 100(0.025V ) = 5.00µA | For VO = 0, VC1 = 0.7V 1MΩ 9 − 0.7 8.3V 8.3V R +r 1.66 MΩ ≅ = = 1.66 MΩ | Rout ≅ C π 3 ≥ = 16.4kΩ RC = IC1 + I B3 IC1 5.00µA 101 β o3 + 1 1MΩ = 2rπ 1 → IC1 = 2 The Rout specification cannot be meet if the Rid specification is met and vice - versa. Either Rid must be reduced or Rout must be increased, or both must be changed. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-55 15.81 (a) For V O = 0, IC 6 = α F I E 6 = α F I3 = IC5 = α F I E 5 = α F βF 4 IC3 αF3 IC 6 βF 6 = 100 (5mA)= 4.95mA 101 4.95mA 49.0µA = 49.0µA | IC 4 + IC 3 = I2 + I B5 = 500µA + = 500µA 100 101 + IC 3 = (β F 3 + 2)IC 3 = 500µA → IC3 = 9.62µA | IC 4 = 500µA − IC3 = 490µA IC1 = IC 2 = α F I1 100 ⎛ 50µA ⎞ = ⎜ ⎟ = 24.8µA | VCE6 = 18 − 0 = 18V | VCE 5 = VCE 6 − VBE6 = 17.3V 2 101 ⎝ 2 ⎠ VEC 4 = 18 − VBE5 − VBE6 = 16.6V | VEC 3 = VEC 4 − VEB 4 = 15.9V VCE1 = VCE2 = 18 − VEB 4 − VEB3 − (−VEB2 )= 17.3V Q − pts : (24.8µA,17.3V) (24.8µA,17.3V) (9.62µA,15.9V) (490µA,16.6V) (49.0µA,17.3V ) (4.95mA,18.0V ) | RC = 1.4V 1.4V = = 56.9kΩ IC 2 − I B 3 ⎛ 9.62 ⎞ ⎜24.8 + ⎟µA 50 ⎠ ⎝ (b) Using the properties of the Darlington configuration from Prob. 15.48 : Adm = ⎞ β o5β o6 RL g ⎛2 g m2 RC Rin3 m4 ⎜ ro4 Rin5 ⎟ 2 2 ⎝3 ⎠ 2rπ 5 + β o5β o6 RL ( ) 50(0.025V ) Rin3 ≅ 2β o3rπ 4 = 2(50) = 255kΩ 490µA 100(0.025V ) + 100(100)(2kΩ)= 20.1MΩ Rin5 ≅ 2β o5rπ 6 + β o5β o6 RL = 2(100) 4.95mA 40(24.8µA) µ ⎛ 20 MΩ ⎞ 70V + 16.6V Rin5 >> ro4 = = 177kΩ | Adm = 56.9kΩ 255kΩ f 4 ⎜ ⎟ 2 3 ⎝ 20.1MΩ ⎠ 490µA ( µf 4 3 Rout = 40(70 + 11.6) 3 = 1155 | Adm = 26500 or (88.5dB) | Rid = 2rπ 1 = 2 100(0.025V ) 2 2 118kΩ + 2 ro4 + 2rπ 5 R + 2rπ 5 3 49.0µA 3 = th5 = = = 18.1 Ω β o5β o6 β o5β o6 100(100) 15-56 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ) 100(0.025V ) 24.8µA = 202 kΩ 15.82 (a) For V O = 0, IC 6 = α F I E 6 = α F I3 = IC5 = α F I E 5 = α F βF 4 IC3 αF3 IC 6 βF 6 = 100 (5mA)= 4.95mA 101 4.95mA 49.0µA = 49.0µA | IC 4 + IC 3 = I2 + I B5 = 500µA + = 500µA 100 101 + IC 3 = (β F 3 + 2)IC 3 = 500µA → IC3 = 9.62µA | IC 4 = 500µA − IC3 = 490µA IC1 = IC 2 = α F I1 100 ⎛ 50µA ⎞ = ⎜ ⎟ = 24.8µA | VCE6 = 22 − 0 = 22V | VCE5 = VCE6 − VBE6 = 21.3V 2 101 ⎝ 2 ⎠ VEC 4 = 22 − VBE5 − VBE6 = 20.6V | VEC 3 = VEC 4 − VEB 4 = 19.9V VCE1 = VCE2 = 22 − VEB 4 − VEB3 − (−VEB2 ) = 21.3V Q − pts : (24.8µA,21.3V ) (24.8µA,21.3V ) (9.62µA,19.9V ) (490µA,20.6V ) (49.0µA,21.3V ) (4.95mA,22.0V ) | RC = 1.4V 1.4V = = 56.9kΩ IC2 − I B 3 ⎛ 9.62 ⎞ ⎜24.8 + ⎟µA 50 ⎠ ⎝ (b) Using the properties of the Darlington configuration from Prob. 15.48 : ⎞⎤⎡ β o5β o6 RL ⎤ ⎡g ⎤⎡ g ⎛ 2 Adm = AV1 AV 2 AV 3 = ⎢ m2 RC Rin3 ⎥⎢ m4 ⎜ ro4 Rin5 ⎟⎥⎢ ⎥ ⎣ 2 ⎦⎣ 2 ⎝ 3 ⎠⎦⎣ 2rπ 5 + β o5β o6 RL ⎦ ( ) 50(0.025V ) = 255kΩ Rin3 ≅ 2β o3rπ 4 = 2(50) 490µA 100(0.025V ) + 100(100)(2kΩ)= 20.1MΩ Rin5 ≅ 2β o5rπ 6 + β o5β o6 RL = 2(100) 4.95mA 40(24.8µA) µ ⎛ 20 MΩ ⎞ 70V + 20.6V Rin5 >> ro4 = = 185kΩ | Adm = 56.9kΩ 255kΩ f 4 ⎜ ⎟ 2 3 ⎝ 20.1MΩ ⎠ 490µA ( µf 4 3 Rout = 40(70 + 20.6) 3 ) = 1208 | Adm = 27700 (88.9dB) | Rid = 2rπ 1 = 2 100(0.025V ) 2 2 185kΩ + 2 ro4 + 2rπ 5 R + 2rπ 5 3 49.0µA 3 = th5 = = = 22.5 Ω β o5β o6 β o5β o6 100(100) 100(0.025V ) 24.8µA = 202 kΩ 15.83 Since the transistor parameters are the same, VGS1 = −VGS 2 = I D2 = I D1 = 2.2V = 1.1V 2 2 6x10−4 1.1− 0.75) = 36.8 µA ( 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-57 15.84 2I D1 ⎛ 2I D2 ⎞ ⎜ ⎟ where I D2 = I D1 − VTP − 2.2V = VGS1 − VGS 2 = VTN + Kn ⎜⎝ K p ⎟⎠ ⎛ 2 ⎞ 0.7 2 ⎟ | 2.2 = 0.7 + 0.8 + I D1 ⎜⎜ + → I D2 = I D1 = 29.7µA I D1 = −4 −4 ⎟ 128.5 4x10 ⎠ ⎝ 6x10 15.85 Since the values of IS and IE are the same, VBE1 = VEB 2 I 1.30 1.30 = VBE1 + VEB 2 = 2VT ln C | IC = 10−15 exp = 196 µA IS 2(0.025V ) 15.86 IC IC IC2 + VT ln = VT ln 1.30 = VBE1 + VEB2 = VT ln I S1 IS 2 I S1 I S 2 IC = 15-58 1.30 = 391 µA (4x10 )(10 )exp 0.025 −15 −15 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.87 vO Slope = 1 +0.7 V vS -0.7 V 15.88 *Problem 15.88 – Figure P15.87 VCC 3 0 DC 10 VEE 5 0 DC -10 VBB 2 1 DC 1.3 VS 1 0 DC 0 Q1 3 2 4 NBJT Q2 5 1 4 PBJT RL 4 0 1K .MODEL NBJT NPN IS=5FA BF=60 .MODEL PBJT PNP IS=1FA BF=50 .OP .DC VS -10 +8.7 0.01 .PROBE .END 10V vO 0V vS -10V -10V -5V 0V 5V 10V 15.89 Since the base currents are zero (β F = ∞), VBE1 + VEB 2 = (250µA)(5kΩ) = 1.25V 1.25V = VT ln IC I I2 +VT ln C = VT ln C IS1 IS 2 IS1IS 2 | IC = 1.25 = 22.8 µA (10 )(10 )exp 0.025 −15 −16 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-59 15.90 VGS1 + VGS 2 = (0.5mA)(4kΩ)= 2.00V | 2.00V = VTN + ⎛ 2 ⎞ 2 ⎟ | 2.00 = 0.75 + 0.75 + I D1 ⎜⎜ + −4 2x10−4 ⎟⎠ ⎝ 5x10 2I D1 ⎛ 2I D2 ⎞ ⎟ | I D2 = I D1 − ⎜⎜VTP − Kn ⎝ K p ⎟⎠ I D1 = 0.5 → I D2 = I D1 = 9.38 µA 163.3 15.91 I SS ≥ 5V 5V = = 5.00mA | iS = I SS + iL RL 1kΩ 5V 5V = I SS + 5.00mA | iSmin = I SS − = I S − 5.00mA 1kΩ 1kΩ = 5.00mA, iSmax = 10.0mA | iSmin = 0 | iD = 0.005(1+ sin 2000πt ) A iSmax = I SS + For I SS Power delivered from the supplies : P (t )= 10V (iD )+ 10V (I SS )= 0.05(2 + sin 2000πt ) W 1 T Pav = T ∫ 0.05(2 + sin 2000πt )dt = 100mW 0 ⎛ 5 ⎞2 1 12.5mW Signal power developed in RL : Pac = ⎜ ⎟ = 12.5mW | η = 100% = 12.5% 100mW ⎝ 2 ⎠ 1kΩ 15.92 +5V T t 0 -5V 15-60 2 2 1 ⎡(+5V ) T (−5V ) T ⎤ ⎥ = 10.0mW Pac = ⎢ + 5kΩ 2 ⎥⎦ T ⎢⎣ 5kΩ 2 1⎡ 5V T −5V T ⎤ − 5V Pav = ⎢5V = 10.0mW T ⎣ 5kΩ 2 5kΩ 2 ⎥⎦ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 | η = 100% 15.93 +10 V t 0 T 4 T 2 T -10 V 2 1 Pac = T T 1 T T Pav = ∫ 0 v 2 (t ) 4 dt = T R ∫ 10i(t )dt = 0 T 4 ∫ 20 T 0 ⎛ 40t ⎞ ⎜ ⎟ 6400 ⎝ T ⎠ dt = 3 T R R T 2 ∫ i(t )dt = 0 40 T T 4 ∫ 0 T 4 ∫ t dt = 0 2 100 3R 1600 40t dt = 2 T R TR T 4 ∫ 0 100 50 tdt = | η = 100% 3R = 66.7% 50 R R 15.94 *Problem 15.94(a) VBB = 0 V VCC 3 0 DC 10 VEE 5 0 DC -10 VBB 2 1 DC 0 VS 1 0 DC 0 SIN(0 4 2000) Q1 3 2 4 NBJT Q2 5 1 4 PBJT RL 4 0 2K .MODEL NBJT NPN IS=5FA BF=60 .MODEL PBJT PNP IS=1FA BF=50 .OP .TRAN 1U 2M .FOUR 2000 V(4) .PROBE .END *Problem 15.94(b) VBB = 1.3 V VCC 3 0 DC 10 VEE 5 0 DC -10 VBB 2 1 DC 1.3 VS 1 0 DC 0 SIN(0 4 2000) Q1 3 2 4 NBJT Q2 5 1 4 PBJT RL 4 0 2K .MODEL NBJT NPN IS=5FA BF=60 .MODEL PBJT PNP IS=1FA BF=50 .OP .TRAN 1U 2M .FOUR 2000 V(4) .PROBE .END ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-61 (a) HARMONIC FREQUENCY FOURIER NORMALIZED NORMALIZED NO (HZ) COMPONENT COMPONENT (DEG) 1 2 3 4 5 6 7 8 9 2.000E+03 4.000E+03 6.000E+03 8.000E+03 1.000E+04 1.200E+04 1.400E+04 1.600E+04 1.800E+04 3.056E+00 2.693E-02 2.112E-01 3.473E-02 7.718E-02 4.064E-02 3.179E-02 4.109E-02 2.127E-02 1.000E+00 8.811E-03 6.910E-02 1.136E-02 2.525E-02 1.330E-02 1.040E-02 1.345E-02 6.960E-03 -4.347E-01 -1.300E+02 -1.744E+02 -1.550E+02 -1.678E+02 -1.679E+02 -1.580E+02 -1.736E+02 -1.568E+02 PHASE PHASE (DEG) 0.000E+00 -1.296E+02 -1.740E+02 -1.545E+02 -1.674E+02 -1.675E+02 -1.576E+02 -1.731E+02 -1.564E+02 TOTAL HARMONIC DISTORTION = 7.831458E+00 PERCENT with VBB = 0 (b) HARMONIC FREQUENCY FOURIER NORMALIZED NORMALIZED NO (HZ) COMPONENT COMPONENT (DEG) 1 2 3 4 5 6 7 8 9 2.000E+03 4.000E+03 6.000E+03 8.000E+03 1.000E+04 1.200E+04 1.400E+04 1.600E+04 1.800E+04 3.853E+00 1.221E-02 1.537E-02 1.504E-02 1.501E-02 1.531E-02 1.435E-02 1.467E-02 1.382E-02 1.000E+00 3.169E-03 3.990E-03 3.903E-03 3.897E-03 3.973E-03 3.726E-03 3.807E-03 3.587E-03 2.544E-01 6.765E+01 9.046E+01 5.520E+01 5.500E+01 4.231E+01 3.680E+01 2.823E+01 2.087E+01 PHASE PHASE (DEG) 0.000E+00 6.740E+01 9.020E+01 5.495E+01 5.475E+01 4.206E+01 3.654E+01 2.798E+01 2.062E+01 TOTAL HARMONIC DISTORTION = 1.064939E+00 PERCENT with VBB = 1.3 V 15-62 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.95 VBE 2 0.7V = = 70.0 mA. R 10Ω 0.07 + 0.7 + 0.7 + 250(0.07) = 19.6 V v S = 1000iB + VBE1 + VBE 2 + 250iE = 1000 101 The current begins to limit at iE = 15.96 *Problem 15.96 – Figure 15.38 VCC 3 0 DC 50 VS 1 0 DC 1 R1 1 2 1K Q1 3 2 4 NBJT Q2 2 4 5 NBJT R 4 5 10 RL 5 0 250 .MODEL NBJT NPN IS=1FA BF=100 .OP .DC VS 1 50 .05 .PROBE .END 120mA Slope = 1k 80mA Ω iL 40mA Slope = 250 Ω 0A 0V 10V 20V vS 30V 40V 50V The results agree well with hand calculations. 15.97 I2 RG = VGS 4 − VGS 5 | (0.25mA)(7kΩ)= VTN 4 + 2I D 4 ⎛ 2I D5 ⎞ ⎟ | I D5 = I D 4 − ⎜⎜VTP5 − 0.005 ⎝ 0.002 ⎟⎠ ⎛ 2 2 ⎞ ⎟ → I D5 = I D 4 = 23.5 µA 1.75 − 0.75 − 0.75 = I D 4 ⎜⎜ + 0.002 ⎟⎠ ⎝ 0.005 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-63 15.98 +15 V 0.2 V 50 Ω Q + 4 + 0.7 V 2.4 k Ω + 1.2 V 0.5 V - For VBE 4 = 0.7V, VEB 5 = I2 RB - VBE 4 - 2k Ω Q VEB 5 = 1.2 − 0.7 = 0.5V and Q 5 is off. VEQ = 15 − 0.2 − 500µA(50Ω) = 14.8V 5 REQ = 50Ω 500 µ A IC 4 = 100 -15 V 15.99 Rout = (14.8 − 0.7)V = 6.98 mA 50Ω + 101(2kΩ) 1 ⎛ rπ ⎞ 1 ⎛ β o ⎞⎛ VT ⎞ 1 ⎛ VT ⎞ 1 ⎛ 0.025V ⎞ ⎜ ⎟ = 25.0 mΩ ⎜ ⎟= ⎜ ⎟⎜ ⎟ = ⎜ ⎟= n 2 ⎝ β o + 1⎠ 100 ⎝ β o + 1⎠⎝ IC ⎠ 100 ⎝ IE ⎠ 100 ⎝ 10mA ⎠ 15.100 IC = 100I B = 100 9 − 0.7 V = 97.9 µA | Looking back into the 200kΩ + 101(82kΩ) Ω transformer : Rth = 1 ⎛ rπ ⎞ 1 100(0.025V ) rπ = = 253Ω ⎟ | 2⎜ β o + 1 101 97.9µA n ⎝ β o + 1⎠ Desire to match the Thevenin equivalent resistance to RL : (β + 1)n R + (β + 1)n R 2 vth = o rπ L 2 o L vs = (101)253 v 25.6kΩ + (101)253 relationships : vth = i1 Rth + nvo | i1 = vo = vth R n + th nRL | vo = s 1 253Ω = 10Ω → n = 5.03 n2 = 0.500v s | Using the ideal transformer 1 1 vo i2 = n n RL | v th = 1 vo Rth + nvo n RL 0.500v s = 0.0497vs | vo = 0.0497sin 2000πt 253Ω 5.03 + 5.03(10Ω) ⎛ 0.0497 ⎞2 1 Po = ⎜ = 0.124 mW ⎟ ⎝ 2 ⎠ 10 15-64 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.101 2 MΩ = −6V | REQ = 2 MΩ 2 MΩ = 1MΩ 2 MΩ + 2 MΩ −6 − 0.7 − (−12) V 100(0.025V ) IO = 100I B = 100 = 22.8 µA | rπ = = 110kΩ 22.8µA 1MΩ + 101(220kΩ) Ω (a) V EQ = −12V (50 + 6.98)V = 2.50 MΩ 101 22.8µA)(220kΩ)= 6.98V | ro = ( 100 22.8µA ⎞ ⎛ ⎛ ⎞ 100(220kΩ) β o RE ⎟ = 43.9 MΩ ⎜ = ro ⎜1+ ⎟ = 2.50 MΩ⎜1+ ⎟ 1MΩ + 110kΩ + 220kΩ ⎝ Rth + rπ + RE ⎠ ⎠ ⎝ VCE = 12 − I E (220kΩ)= 12 − Rout (b) Using the CVD model for the diode, 2 MΩ VEQ = −12 + (12V − 0.7V ) + 0.7 = −5.65V | REQ = 2 MΩ 2 MΩ = 1MΩ 2 MΩ + 2 MΩ −5.65 − 0.7 − (−12) V 100(0.025V ) IO = 100I B = 100 = 24.3 µA | rπ = = 103kΩ 24.3µA 1MΩ + 101(220kΩ) Ω (50 + 6.60)V = 2.33MΩ 101 24.3µA)(220kΩ)= 6.60V | ro = ( 100 24.3µA ⎞ ⎛ ⎛ ⎞ 100(220kΩ) β o RE ⎟ = 41.1 MΩ = ro ⎜1+ ⎟ = 2.33MΩ⎜⎜1+ ⎟ ⎝ Rth + rπ + RE ⎠ ⎝ 1MΩ + 103kΩ + 220kΩ ⎠ VCE = 12 − I E (220kΩ)= 12 − Rout 15.102 The dc analysis is the same as Problem 15.101. However, the bypass capacitor provides as ac ground at the base of the transistor so that Rth = 0. ⎛ ⎛ 100(220kΩ) ⎞ β o RE ⎞ ⎟ = 169 MΩ ⎜ Rout = ro ⎜1+ ⎟ = 2.50 MΩ⎜1+ ⎟ 110kΩ + 220kΩ ⎝ rπ + RE ⎠ ⎠ ⎝ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-65 15.103 430kΩ = −5.53V | REQ = 270kΩ 430kΩ = 166kΩ 270kΩ + 430kΩ −5.53 − 0.7 − (−9) 150(0.025V ) V = 144 µA | rπ = = 26.0kΩ IO = 100I B = 150 144µA 166kΩ + 151(18kΩ) (a) V EQ = −9V (75 + 6.39)V = 565kΩ 151 144µA)(18kΩ)= 6.39V | ro = ( 144µA 150 ⎛ ⎞ ⎛ ⎞ 150(18kΩ) β o RE ⎟ = 7.83 MΩ = ro⎜1+ ⎟ = 565kΩ⎜⎜1+ ⎟ ⎝ Rth + rπ + RE ⎠ ⎝ 166kΩ + 26.0kΩ + 18kΩ ⎠ VCE = 9 − I E (18kΩ) = 9 − Rout (b) Using the CVD model for the diode, ⎛ ⎞ 270kΩ VEQ = −9 + (9V − 0.7V )⎜ ⎟ + 0.7 = −5.10V | REQ = 270kΩ 430kΩ = 166kΩ ⎝ 270kΩ + 430kΩ ⎠ IO = 100I B = 150 −5.10 − 0.7 − (−9) V = 166 µA | rπ = 166kΩ + 151(18kΩ) 150(0.025V ) 166µA = 22.6kΩ (75 + 5.99)V = 488kΩ 151 166µA)(18kΩ)= 5.99V | ro = ( 166µA 150 ⎛ ⎞ ⎛ ⎞ 150(18kΩ) β o RE ⎟ = 6.87 MΩ Rout = ro⎜1+ ⎟ = 488kΩ⎜⎜1+ ⎟ 166kΩ + 22.6kΩ + 18kΩ ⎝ Rth + rπ + RE ⎠ ⎝ ⎠ 200kΩ (c) VEQ = −5V 100kΩ + 200kΩ = −3.33V | REQ = 100kΩ 200kΩ = 66.7kΩ −3.33 − 0.7 − (−5) 100(0.025V ) IO = 100I B = 100 V = 61.3 µA | rπ = = 40.8kΩ 61.3µA 66.7kΩ + 101(15kΩ) VCE = 9 − I E (18kΩ) = 9 − (75 + 4.07)V = 1.29 MΩ 101 61.3µA)(15kΩ)= 4.07V | ro = ( 61.3µA 100 ⎛ ⎞ ⎛ ⎞ 100(15kΩ) β o RE ⎜ ⎟ = 1.29 MΩ 1+ = ro⎜1+ ⎟ ⎜ 66.7kΩ + 40.8kΩ + 15kΩ ⎟ = 17.1 MΩ ⎝ Rth + rπ + RE ⎠ ⎝ ⎠ VCE = 5 − I E (15kΩ)= 5 − Rout (d ) Using the CVD model for the diode, ⎛ ⎞ 100kΩ VEQ = −5 + (5V − 0.7V )⎜ ⎟ + 0.7 = −2.87V | REQ = 100kΩ 200kΩ = 66.7kΩ ⎝100kΩ + 200kΩ ⎠ IO = 100I B = 100 −2.87 − 0.7 − (−5) V = 90.4 µA | rπ = 66.7kΩ + 101(15kΩ) 100(0.025V ) 90.4µA = 27.7kΩ (75 + 3.63)V = 870kΩ 101 90.4µA)(15kΩ)= 3.63V | ro = ( 100 90.4µA ⎛ ⎞ ⎛ ⎞ 100(15kΩ) β o RE ⎟ = 12.8 MΩ = ro⎜1+ ⎟ = 870kΩ⎜⎜1+ ⎟ ⎝ Rth + rπ + RE ⎠ ⎝ 66.7kΩ + 27.7kΩ + 15kΩ ⎠ VCE = 5 − I E (15kΩ)= 5 − Rout 15-66 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.104 2MΩ = −6V | REQ = 2MΩ 2MΩ = 1MΩ 2MΩ + 2MΩ −6 − 0.7 − (−12) V 100(0.025V ) IO = 100IB = 100 = 22.8 µA | rπ = = 110kΩ 1MΩ + 101(220kΩ) Ω 22.8µA (a) VEQ = −12V 101 (50 + 6.98)V = 2.50MΩ (22.8µA)(220kΩ) = 6.98V | ro = 100 22.8µA ⎞ ⎞ ⎛ ⎛ 100(220kΩ) β o RE Rout = ro⎜1+ ⎟ = 2.50MΩ⎜1+ ⎟ = 43.9 MΩ ⎝ Rth + rπ + RE ⎠ ⎝ 1MΩ + 110kΩ + 220kΩ ⎠ (b) Using the CVD model for the diode (diode - connected transistor), VCE = 12 − IE (220kΩ) = 12 − 2 MΩ VEQ = −12 + (12V − 0.7V ) + 0.7 = −5.65V | REQ = 2 MΩ 2 MΩ = 1MΩ 2 MΩ + 2 MΩ −5.65 − 0.7 − (−12) V 100(0.025V ) IO = 100I B = 100 = 24.3 µA | rπ = = 103kΩ 24.3µA 1MΩ + 101(220kΩ) Ω (50 + 6.60)V = 2.33MΩ 101 24.3µA)(220kΩ)= 6.60V | ro = ( 100 24.3µA ⎞ ⎛ ⎛ ⎞ 100(220kΩ) β o RE ⎟ ⎜ = ro ⎜1+ = 2.33MΩ 1+ ⎟ ⎜ 1MΩ + 103kΩ + 220kΩ ⎟ = 41.1 MΩ ⎝ Rth + rπ + RE ⎠ ⎠ ⎝ VCE = 12 − I E (220kΩ) = 12 − Rout 15.105 IC R 1 IC RB Q R Q V 2 RE -12 V B RE -12 V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-67 A spread sheet will be used to assist in this design using β F = β o = 100 & VA = 70V The maximum current in the two bias resistors is 0.2mA. To allow some room for tolerances, choose I1 ≅ 0.15mA. Neglecting the transistor base current, 12V V V = 80kΩ | R2 = B (R1 + R2 ) = B 80kΩ | RB = R1 R2 0.15mA 12 12 (VB − 0.7) or R = 1 ⎛⎜100(VB − 0.7) − R ⎞⎟ | V = 12 − I R IC = 100 E B⎟ CE E E 101 ⎜⎝ RB + 101RE IC ⎠ ⎛ ⎞ β o RE 70 + VCE ro = | Rout = ro ⎜1+ ⎟ IC ⎝ RB + rπ + RE ⎠ Now, a spreadsheet MATLAB, MATHCAD, etc. can be used to explore the design space with VB as the primary design variable. R1 + R2 = VB R2 R1 RB 0.500 0.600 0.700 0.800 0.900 1.000 1.100 1.200 1.300 1.400 1.500 1.600 1.700 1.800 1.900 2.000 3.33E+03 4.00E+03 4.67E+03 5.33E+03 6.00E+03 6.67E+03 7.33E+03 8.00E+03 8.67E+03 9.33E+03 1.00E+04 1.07E+04 1.13E+04 1.20E+04 1.27E+04 1.33E+04 7.67E+04 7.60E+04 7.53E+04 7.47E+04 7.40E+04 7.33E+04 7.27E+04 7.20E+04 7.13E+04 7.07E+04 7.00E+04 6.93E+04 6.87E+04 6.80E+04 6.73E+04 6.67E+04 3.19E+03 3.80E+03 4.39E+03 4.98E+03 5.55E+03 6.11E+03 6.66E+03 7.20E+03 7.73E+03 8.24E+03 8.75E+03 9.24E+03 9.73E+03 1.02E+04 1.07E+04 1.11E+04 -2.30E+02 -1.74E+05 -1.37E+02 -8.00E+04 -4.35E+01 1.41E+04 4.97E+01 1.08E+05 1.43E+02 2.03E+05 2.37E+02 2.97E+05 3.30E+02 3.91E+05 4.24E+02 4.86E+05 5.18E+02 5.81E+05 6.11E+02 6.76E+05 7.05E+02 7.71E+05 8.00E+02 8.66E+05 8.94E+02 9.61E+05 9.88E+02 1.06E+06 1.08E+03 1.15E+06 1.18E+03 1.25E+06 5.57E+05 9.73E+04 5.13E+03 1.80E+05 5.56E+05 1.09E+06 1.75E+06 2.52E+06 3.38E+06 4.31E+06 5.32E+06 6.38E+06 7.50E+06 8.68E+06 9.90E+06 1.12E+07 7.50E+04 6.80E+04 5.73E+03 1.02E+04 1.50E+02 1.00E+03 5.85E+05 8.86E+06 RE ro Rout Two possible solutions 0.916 1.800 6.20E+03 1.20E+04 2.10E+05 1.07E+06 IO 1.04E-03 9.89E-04 The first solution is the lowest value of VB that was found to meet the output specification using the nearest 5% values. The second is one in which the values were found to be very close to existing standard 5% resistor values, but it uses twice the value of VB and has a smaller output voltage compliance range. 15-68 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.106 330kΩ 10V = 3.27V | REQ = 330kΩ 680kΩ = 222kΩ 330kΩ + 680kΩ ⎛ 5x10−4 ⎞ 2 Assume active region operation : I D = ⎜ ⎟(VGS −1) ⎝ 2 ⎠ ⎛ 5x10−4 ⎞ 2 VGS = 3.27 − (33kΩ)I D = 3.27 − 33x103 ⎜ ⎟(VGS −1) ⇒ VGS = 1.467V | IO = I D = 54.5 µA ⎝ 2 ⎠ VEQ = VDS = 10 − (33kΩ)I D = 8.20V | Active region operation is correct. ro = 100 + 8.20 V = 1.99 MΩ | g m = 2 5x10−4 54.5x10−6 1+ (0.01)8.20 = 0.243 mS 54.5 µA ( [ ( )] )( [ )[ ] ] Rout = ro 1+ g m 33x103 = 1.99 MΩ 1+ 0.243mS (33kΩ) = 17.9 MΩ 15.107 68kΩ 3V = 0.760V | REQ = 68kΩ 200kΩ = 50.8kΩ 68kΩ + 200kΩ < VTN , (0.76V < 1V) so the transistor is off, and IO = ID = 0. VEQ = VEQ The circuit designer made an error and failed to check the final design. 15.108 100kΩ 6V = 2V | REQ = 100kΩ 200kΩ = 66.7kΩ 100kΩ + 200kΩ ⎛ 5x10−4 ⎞ 2 Assume active region operation : 2 = VGS + (16kΩ)I D | I D = ⎜ ⎟(VGS −1) ⎝ 2 ⎠ VEQ = 4VGS2 − 7VGS + 2 = 0 ⇒ VGS = 1.390V | IO = I D = 38.1 µA VDS = VO − (16kΩ)I D = 6 − (16kΩ)(38.1µA)= 5.39V | Active region is correct. ro = 100 + 5.39 V = 2.77 MΩ | g m ≅ 2 5x10−4 38.1x10−6 1+ 0.01(5.39) = 0.200 mS 38.1 µA ( [ ( )] [ )( )[ ] ] Rout = ro 1+ g m 16x103 = 2.77 MΩ 1+ 0.200mS (16kΩ) = 11.6 MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-69 15.109 200kΩ = 10V | REQ = 200kΩ 100kΩ = 66.7kΩ 200kΩ + 100kΩ (15 − 0.7 −10)V = 88.6 µA | r = 75(0.025V ) = 21.2kΩ IO = 75I B = 75 π 88.6µA 66.7kΩ + 76(47kΩ) VEQ = 15V (50 + 10.7)V = 685kΩ 76 88.6 µA)(47kΩ) = 10.7V | ro = ( 75 88.6µA ⎛ ⎞ ⎛ ⎞ 75(47kΩ) β o RE ⎟ = 18.6 MΩ = ro ⎜1+ ⎟ = 685kΩ⎜⎜1+ ⎟ ⎝ Rth + rπ + RE ⎠ ⎝ 66.7kΩ + 21.2kΩ + 47kΩ ⎠ VEC = 15 − I E RE = 15 − Rout 15.110 33kΩ = 3.84V | REQ = 33kΩ 10kΩ = 7.67kΩ 33kΩ + 10kΩ 75(0.025V ) 5 − 0.7 − 3.84 IO = 75IB = 75 V = 284 µA | rπ = = 6.60kΩ 284 µA 7.67kΩ + 76(1.5kΩ) VEQ = 5V 76 (60 + 4.57)V = 227kΩ (284 µA)(1.5kΩ) = 4.57V | ro = 75 284 µA ⎞ ⎞ ⎛ ⎛ 75(1.5kΩ) β o RE = ro⎜1+ ⎟ = 227kΩ⎜1+ ⎟ = 1.85 MΩ ⎝ Rth + rπ + RE ⎠ ⎝ 7.67kΩ + 6.60kΩ + 1.5kΩ ⎠ VEC = 5 − IE RE = 5 − Rout 15.111 300kΩ = 7.50V | REQ = 300kΩ 100kΩ = 75.0kΩ 300kΩ + 100kΩ 90(0.025V ) 10 − 0.7 − 7.50 V = 94.6 µA | rπ = = 23.4kΩ IO = 90I B = 90 94.6µA 75.0kΩ + 91(18kΩ) VEQ = 10V (75 + 8.28)V = 880kΩ 91 94.6µA)(18kΩ)= 8.28V | ro = ( 90 94.6µA ⎛ ⎞ ⎛ ⎞ 90(18kΩ) β o RE ⎟ = 13.1 MΩ = ro⎜1+ ⎟ = 880kΩ⎜⎜1+ ⎟ ⎝ Rth + rπ + RE ⎠ ⎝ 75.0kΩ + 23.4kΩ + 18kΩ ⎠ VEC = 10 − I E RE = 10 − Rout 15-70 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.112 200kΩ 6V = 4V | REQ = 200kΩ 100kΩ = 66.7kΩ | 6 −162 −16e3* x103 I D + VGS = 4 200kΩ + 100kΩ 2 7.5x10−4 Assume active region operation : I D = VGS + 0.75) ( 2 3 2 −16x10 I D + VGS = 0 ⇒ VGS = −1.13V | IO = I D = 54.3 µA VEQ = ( ) VDS = − 6 −16x103 I D = −5.13V | Active region is correct. ro = 100 + 5.13 V = 1.94 MΩ | g m = 2 7.5x10−4 54.3x10−6 1+ 0.01(5.13) = 0.292mS 54.3 µA ( )( [ )[ ] ] Rout = ro (1+ g m RS )= 1.94 MΩ 1+ 0.292mS (16kΩ) = 11.0 MΩ 15.113 VEQ = 9V 2 MΩ = 6V | REQ = 2 MΩ 1MΩ = 667kΩ | 9 −105 I D + VGS = 6 2 MΩ + 1MΩ Assume active region operation : VGS = VTP − 2I D Kp ⎛ 2I D ⎞ ⎟ ⇒ IO = I D = 17.0 µA 1.2x105 I D = 3 + ⎜⎜ −0.75 − 7.5x10−4 ⎟⎠ ⎝ ( ) VDS = − 9 −1.2x105 I D = −6.96V | Active region is correct. ro = 100 + 6.96 V = 6.29 MΩ | g m = 2 7.5x10−4 17.0x10−6 1+ 0.01(6.96) = 0.165mS 17.0 µA Rout = ro (1+ g m ( )( )[ R )= 6.29 MΩ[1+ 0.165mS (1.2x10 )]= 131 MΩ ] 5 S 15.114 VEQ = 200kΩ 4V = 3.05V | REQ = 200kΩ 62kΩ = 47.3kΩ 200kΩ + 62kΩ Assume active region operation : 4 − 43x103 I D + VGS = 3.05 | I D = 2 7.5x10−4 VGS + 0.75) ( 2 0.95 − 43x103 I D + VGS = 0 ⇒ VGS = −0.6034V | IO = I D = 8.06 µA ( ) VDS = − 4 − 43x103 I D = −3.65V | Active region is correct. ro = 100 + 3.65 V = 12.9 MΩ | g m = 2 7.5x10−4 8.06x10−6 1+ 0.01(3.65) = 112 µS 8.06 µA ( [ )( )[ ] ] Rout = ro (1+ g m RS )= 12.9 MΩ 1+ 112µS (43kΩ) = 75.0 MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-71 15.115 50V ⎛ ⎞ ⎜1+ 2 2x10−4 1.75x10−4 RS ⎟ −4 ⎝ ⎠ 1.75x10 Note that including λ in the g m expression will increase Rout above this estimate. ( Estimating Rout ≅ ro (1+ g m RS )≅ )( ) Hence neglecting λ represents a conservative simplification. ( ) 286kΩ 1+ 2.65x10−4 RS ≥ 2.5MΩ ⇒ RS ≥ 29.2kΩ | Choose RS = 33kΩ ⎛ ⎞ 2 1.75x10−4 ⎟ ⎜ VG = VDD − I D RS + VGS = 12 −1.75x10 3.3x10 + −1− = 3.90V ⎜ 2x10−4 ⎟ ⎝ ⎠ 12V R4 12 = 3.90 | I2 ≤ 25µA | Assign I2 = 20µA | R3 + R4 = = 600kΩ R3 + R4 20µA −4 ( 4 ) ( ) 3.90 (R3 + R4 ) = 195kΩ ⇒ R4 = 200kΩ | R3 = 430kΩ 12 15.116 68kΩ (a) VEQ = −12V 68kΩ + 33kΩ = −8.08V | REQ = 68kΩ 33kΩ = 22.2kΩ | VB = −8.08 − (I B1 + I B2 )RTH ⎛ V − 0.7 − (−12) V − 0.7 − (−12)⎞ B B ⎟22.2kΩ → VB = −8.11V VB = −8.08 − ⎜⎜ + 126(100kΩ) ⎟⎠ ⎝ 126(20kΩ) 125 ⎛⎜ VB − 0.7 − (−12)⎞⎟ 125 ⎛⎜ VB − 0.7 − (−12)⎞⎟ µ A | I = α I = IC1 = α F I E1 = = 158 C2 F E2 ⎟ ⎟ = 31.7 µA 126 ⎜⎝ 126 ⎜⎝ 20kΩ 100kΩ ⎠ ⎠ R4 = VCE = 0 − (−8.11− 0.7)= 8.87V | ro1 = rπ 1 = 125(0.025V ) 158 µA = 19.8kΩ | rπ 2 = (50 + 8.11)V = 368kΩ | 158µA 125(0.025V ) 31.7µA [ [ = 98.6kΩ ] R th1 = 22.2kΩ 98.6kΩ + (126)(100kΩ) = 22.2kΩ ⎛ ⎞ ⎛ ⎞ 125(20kΩ) β o RE ⎜ ⎟ Rout1 = ro1⎜1+ = 368kΩ 1+ ⎟ ⎜ 22.2kΩ + 19.8kΩ + 20kΩ ⎟ = 15.2 MΩ ⎝ Rth + rπ 1 + RE ⎠ ⎝ ⎠ ro2 = (50 + 8.11)V = 1.83MΩ 31.7µA [ [ ] | Rth2 = RTH rπ 1 + (β o + 1)(20kΩ) ] Rth2 = 22.2kΩ 19.8kΩ + (126)(20kΩ) = 22.0kΩ ⎛ ⎞ ⎛ ⎞ 125(100kΩ) β o RE ⎜ ⎟ Rout2 = ro2⎜1+ = 1.83MΩ 1+ ⎟ ⎜ 22.0kΩ + 98.6kΩ + 100kΩ ⎟ = 106 MΩ ⎝ Rth + rπ 2 + RE ⎠ ⎝ ⎠ 15-72 ] Rth1 = REQ rπ 2 + (β o + 1)(100kΩ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.116 cont. (b) Using the CVD model for diode Q for dc calculations, (12V − 0.7) 68kΩ = −7.61V | R = 68kΩ 33kΩ = 22.2kΩ | V = −8.08 − I + I R V = ( ) ( ) 68kΩ + 33kΩ ⎛ V − 0.7 − (−12) V − 0.7 − (−12)⎞ ⎟22.2kΩ → V = −7.65V V = −7.61− ⎜⎜ + ⎟ 126 20kΩ 126 100kΩ ( ) ( ) ⎠ ⎝ 125 ⎛ V − 0.7 − (−12)⎞ 125 ⎛ V − 0.7 − (−12)⎞ ⎜ ⎟ = 181 µA | I = α I = ⎜ ⎟ = 36.2 µA I =α I = 3 EQ EQ B B EQ B F E1 126 ⎜⎝ B 20kΩ ⎟ ⎠ C2 VCE = 0 − (−7.65 − 0.7)= 8.35V | ro1 = rπ 1 = B2 B B C1 B1 125(0.025V ) 181 µA = 17.3kΩ | rπ 2 = [ F E2 (50 + 8.35)V = 322kΩ | 181µA 125(0.025V ) 36.2µA 126 ⎜⎝ B 100kΩ [ ⎟ ⎠ ] Rth1 = REQ rπ 2 + (β o + 1)(100kΩ) = 86.3kΩ ] Rth1 = 22.2kΩ 86.3kΩ + (126)(100kΩ) = 22.2kΩ ⎞ ⎛ ⎛ ⎞ 125(20kΩ) β o RE ⎟ ⎜ Rout1 = ro1⎜1+ = 322kΩ 1+ ⎟ ⎜ 22.2kΩ + 17.3kΩ + 20kΩ ⎟ = 13.9 MΩ ⎝ Rth + rπ 1 + RE ⎠ ⎠ ⎝ ro2 = (50 + 8.35)V = 1.61MΩ 36.2µA [ [ ] | Rth2 = RTH rπ 1 + (β o + 1)(20kΩ) ] Rth2 = 22.2kΩ 17.3kΩ + (126)(20kΩ) = 22.0kΩ ⎛ ⎞ ⎛ ⎞ 125(100kΩ) β o RE ⎜ ⎟ = 98.2 MΩ Rout2 = ro2 ⎜1+ ⎟ = 1.61MΩ⎜1+ ⎟ 22.0kΩ + 86.3kΩ + 100kΩ ⎝ Rth + rπ 2 + RE ⎠ ⎝ ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-73 15.117 20kΩ = −4.07V | REQ = 20kΩ 39kΩ = 13.2kΩ 20kΩ + 39kΩ ⎛ 1 VB + 0.7 1 VB + 0.7 1 VB + 0.7 ⎞ I B = −⎜ + + ⎟ | VB = −4.07V + 13200I B → VB = −3.95V 76 16kΩ 76 8.2kΩ ⎠ ⎝ 76 33kΩ ⎛ β o (33kΩ) ⎞ 75 ⎛ 0 − 0.7V − (−3.95V )⎞ ⎟ = 97.2µA | Rout1 = ro1⎜1+ ⎟ IC1 = ⎜⎜ ⎜ R + r + 33kΩ ⎟ ⎟ 76 ⎝ 33kΩ th1 π 1 ⎝ ⎠ ⎠ VEQ = −12V [ ][ ] Rth1 = 13.2kΩ rπ 2 + (β o2 + 1)16kΩ rπ 3 + (β o3 + 1)8.2kΩ ≅ 13.2kΩ Rout1 = IC2 = ⎞ 75(33kΩ) 60 + 8.75 ⎛ ⎜1+ ⎟ = 27.4 MΩ 97.2µA ⎜⎝ 13.2kΩ + 19.3kΩ + 33kΩ ⎟⎠ ⎛ β o (16kΩ) ⎞ 75 ⎛ 0 − 0.7V − (−3.95V )⎞ ⎜ ⎟ = 201µA | Rout2 = ro2 ⎜1+ ⎟ ⎜ R + r + 16kΩ ⎟ ⎟ 76 ⎜⎝ 16kΩ th2 π2 ⎝ ⎠ ⎠ [ ][ ] Rth2 = 13.2kΩ rπ 1 + (β o1 + 1)33kΩ rπ 3 + (β o3 + 1)8.2kΩ ≅ 13.2kΩ ⎞ 75(16kΩ) 60 + 8.75 ⎛ ⎜ ⎟ = 11.0 MΩ Rout2 = 1+ 201µA ⎜⎝ 13.2kΩ + 9.33kΩ + 16kΩ ⎟⎠ ⎛ β o (8.2kΩ) ⎞ 75 ⎛ 0 − 0.7V − (−3.95V )⎞ ⎜ ⎜ ⎟ ⎟ IC3 = ⎜ ⎟ = 391µA | Rout3 = ro3 ⎜1+ R + r + 8.2kΩ ⎟ 76 ⎝ 8.2kΩ th2 π2 ⎝ ⎠ ⎠ [ ][ ] Rth3 = 13.2kΩ rπ 1 + (β o1 + 1)33kΩ rπ 2 + (β o2 + 1)16kΩ ≅ 13.2kΩ ⎞ 75(8.2kΩ) 60 + 8.75 ⎛ ⎜ ⎟ = 4.30 MΩ Rout3 = 1+ 391µA ⎜⎝ 13.2kΩ + 4.80kΩ + 8.2kΩ ⎟⎠ 15-74 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.118 2 MΩ = 6.00V | REQ = 2 MΩ 2 MΩ = 1.00 MΩ 2 MΩ + 2 MΩ 2I D1 Assume saturation : 12 −105 I D1 + VGS1 = 6 | VGS1 = −1− 2.5x10−4 I D1 = 44.1 µA, VGS1 = −1.59V , VDS1 = −(6 − VGS1 )= −7.59V VEQ = 12V Rout1 = ro1(1+ g m1 R1 )= 50V + 7.59V ⎛ ⎞ ⎜1+ 100kΩ 2(250µA)(44.1µA) 1+ 0.02(7.69) ⎟ = 22.2 MΩ ⎝ ⎠ 44.1µA [ ] 2I D2 2.5x10−4 I D2 = 10.0 µA, VGS 2 = −1.28 V , VDS 2 = −(6 − VGS 2 ) = −7.28V 12 − 4.7x105 I D2 + VGS 2 = 6 | VGS 2 = −1− Rout2 = ro2 (1+ g m2 R2 )= 50V + 7.28V ⎛ ⎞ ⎜1+ 470kΩ 2(250µA)(10.0µA) 1+ 0.02(7.28) ⎟ = 210 MΩ ⎝ ⎠ 10.0µA [ ] 15.119 *Problem 15.119 – Figure P15.118 VCC 1 0 DC 12 R1 1 2 100K R4 1 3 2MEG R3 3 0 2MEG R2 1 4 470K M1 5 3 2 2 PFET M2 6 3 4 4 PFET VD1 5 0 DC 0 VD2 6 0 DC 0 .MODEL PFET PMOS VTO=-1 KP=250U LAMBDA=0.02 .OP *.TF I(VD1) VD1 .TF I(VD2) VD2 .END Results: IO1 = 44.4 µA, ROUT1 = 22.1 MΩ, IO1 = 10.1 µA, ROUT1 = 209 MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-75 15.120 For large A, IO ≅ α F VREF 120 5V = = 99.2 µA 121 50kΩ R vx + v -A v e rπ ix gmv ve ro R For the small - signal model above, vx = ve + (ix − g mv )ro | v = (− Av e )− ve = −ve (1+ A) | ix = Gve + g π (1+ A)ve | Combining : Rout = ro = Rout vx 1+ µ f (1+ A) 1 = + ≅ ro (1+ β o ) for g π (1+ A)>> G and µ f (1+ A)>> 1 ix G + g π (1+ A) g o 50V + 10V = 605kΩ | Rout = 605kΩ(121)= 73.2 MΩ 99.2µA cannot exceed β oro because of the loss of base current through rπ . 15.121 ROUT is limited to βoro of the BJT. We need to increase the effective current gain of the transistor which can be done by replacing Q1 with a Darlington configuration of two transistors. +V CC I o + V REF A Q 2 Q1 R -V EE 2 2 Now ROUT can approach the βoro product of the Darlington which is Rout ≅ β o ro2 . See Prob. 3 15.48 15-76 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.122 For large A, IO ≅ VREF 5V = = 100µA 50kΩ R vx + v -A v s gm v - ix ro vs R For the small - signal model above, v x = v s + (ix − gm v )ro | v = (−Av s ) − v s = −v s (1+ A) | v s = ix R | Combining : Rout = vx 50V + 10V = R + ro [1+ gm R(1+ A)] | ro = = 600kΩ 100µA ix gm = 2(8x10−4 )(10−4 )[1+ 0.02(10)] = 0.438mS [ ] Rout = 50kΩ + 600kΩ 1+ 0.438mS (50kΩ)(1+ 5x10 4 ) = 6.57x1011 Ω !! 15.123 91kΩ = 9.03V | REQ = 91kΩ 30kΩ = 22.6kΩ 91kΩ + 30kΩ 12 − 0.7 − 9.03 V = 9.34 µA IC 3 = 85I B 3 = 85 22.6kΩ + 86(240kΩ) Ω (a) V EQ = 12V 86 (9.34µA)(240kΩ)− 0.7 = 9.03V 85 85 ⎛ 9.34µA ⎞ I IC1 = IC 2 = α F C 3 = ⎜ ⎟ = 4.62µA | VEC1 = VEC 2 = 0.7 − −12 + 1.2 MΩ(4.62µA) = 7.16V 86 ⎝ 2 ⎠ 2 VEC 3 = 12 − I E RE − 0.7 = 12 − [ ] Q − po int s : (4.62µA,7.62V ) (4.62µA,7.62V ) (9.34µA,9.03V ) (b) r π3 = 85(0.025V ) 9.34µA = 228kΩ | ro3 = (70 + 9.03)V = 8.46 MΩ 9.34µA ⎛ ⎞ ⎛ ⎞ 85(240kΩ) β o RE ⎟ = 360 MΩ Rout 3 = ro3⎜1+ ⎟ = 8.46 MΩ⎜⎜1+ ⎟ ⎝ Rth + rπ 3 + RE ⎠ ⎝ 22.6kΩ + 228kΩ + 240kΩ ⎠ g m RC = 20(4.62µA)(1.2 MΩ) = +111 (40.9dB) 2 CMRR = g m1 Rout 3 = 40(4.62µA)(360 MΩ)= 6.65x10 4 (96.5dB) For a single - ended output, Av = (c) The answers are the same as parts (a) and (b). ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-77 15.124 (a) V EQ = −15V 100kΩ = −9.93V | REQ = 100kΩ 51kΩ = 33.8kΩ | Assume saturation : 100kΩ + 51kΩ −9.93 = −15 + 7500I D 3 + VGS 3 | VGS 3 = 1+ I D1 = I D 2 = 2I D3 | I D3 = 363 µA, VGS 3 = 2.35V 4x10−4 2(363µA) I D3 = 182µA | VGS 1 = 1+ = 1.95V 2 2(400µA) VDS 3 = −VGS 1 − 7500I D 3 − (−15)= 10.3V VDS1 = VDS 2 = VD1 − VS 1 = 15 − 36000I D1 − (−VGS 1)= 10.4V (182µA, 10.4V ) (182µA, 10.4V ) (363µA, 10.3V ) 50V + 10.3V = 166kΩ 363µA ⎛ ⎞ Rout 3 = ro3 (1+ g m3 RS )= 166kΩ⎜1+ 2 4x10−4 3.63x10−4 1+ 0.02(10.3) (7.5kΩ)⎟ = 903 kΩ ⎝ ⎠ (b) r o3 = ( ( ) ( )( Add = −g m RD ro2 = − 2 4x10−4 1.82x10−4 For a single - ended output, Acd ≅ − CMRR = )( )[ ] )[1+ 0.02(10.4)](36kΩ 332kΩ)= 0.419mS (325kΩ)= −13.6 RD 36kΩ =− = −0.199 2Rout 3 2(903kΩ) 13.6 / 2 = 342 or 50.7 dB 0.0199 The approximate CMRR estimate is CMRR ≅ g m1 Rout 3 = 0.419mS (903kΩ) = 378 (51.6 dB) 15.125 ro1 since the collector current of the 2 current source is twice that of the input transistors. For a single- ended output, Assuming all devices are identical, Rout = β o1 Add = − β µ g m1 RC RC R g β r | Acc = − = − C | CMRR = m1 o1 o1 = o1 f 1 ⎛ r ⎞ 2 β o1ro1 2 2 2⎜β o1 o1 ⎟ 2⎠ ⎝ Using our default paramters: CMRR ≅ 20β o1VA1 = 20(100)(70)= 140,000 (103dB) (Note that this analysis neglects the contribution of the output resistance ro of the input pair. If this resistance is included, a theoretical cancellation occurs and Acc = 0! Of course the output β o ro resistance expression Rout = is not precise, but an improvement over the CMRR expression 2 above is possible.) 15-78 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.126 Rout = ro (1+ g m RS ) ≅ µF RS = g mro RS ≅ 2Kn I D VR S = I D RS = ( ) λ I D1.5 Rout 2Kn = 1 R λI D S ( ) (5x10 ) = 3.16 V 2(5x10 ) 0.02 10−4 1.5 6 −4 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-79 15.127 *Problem 15.127 - Fig. 15.49(a) - BJT Current Source Monte Carlo Analysis *Generate a Voltage Source with 5% Tolerances IEE 0 5 DC 1 REE 5 0 RTOL 15 EEE 1 0 5 0 -1 * VO 4 0 AC 1 RE 1 2 RTOL 18.4K R1 1 3 RTOL 113K R2 3 0 RTOL 263K Q1 4 3 2 NBJT .OP .DC VO 0 0 .01 .AC LIN 1 1000 1000 .PRINT AC IM(VO) IP(VO) .MODEL NBJT NPN BF=150 VA=75 .MODEL RTOL RES (R=1 DEV 5%) .MC 1000 DC I(VO) YMAX *.MC 1000 AC IM(VO) YMAX .END Results - 3σ limits: IO = 199 µA ± 32.5 µA, ROUT = 11.8 MΩ ± 2.6 MΩ *Problem 15.127 - Fig. 15.49(b) - MOSFET Current Source *Generate a Voltage Source with 5% Tolerance IEE 0 5 DC 1 REE 5 0 RTOL 15 EEE 1 0 5 0 -1 * VO 4 0 AC 1 RS 1 2 RTOL 18K R3 1 3 RTOL 240K R4 3 0 RTOL 510K M1 4 3 2 2 NFET .OP .DC VO 0 0 .01 .AC LIN 1 1000 1000 .PRINT AC IM(VO) IP(VO) .MODEL NFET NMOS KP=9.95M VTO=1 LAMBDA=0.01 .MODEL RTOL RES (R=1 DEV 5%) .MC 1000 DC I(VO) YMAX *.MC 1000 AC IM(VO) YMAX .END Results - 3σ limits: IO = 201 µA ± 34.7 µA, ROUT = 21.7 MΩ ± 3.6 MΩ 15-80 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.128 4.02kΩ(1+ 0.15)(1− 0.03) ≤ R ≤ 4.02kΩ(1+ 0.15)(1+ 0.03) | 4.48kΩ ≤ R ≤ 4.76kΩ 15.129 ⎛V ⎞ ⎛V ⎞ I ⎛V − V ⎞ I IC1 = I S1 exp⎜ BE1 ⎟ | IC2 = I S 2 exp⎜ BE 2 ⎟ | C2 = S 2 exp⎜ BE 2 BE1 ⎟ | ∆VBE = VBE2 − VBE1 VT ⎝ VT ⎠ ⎝ VT ⎠ IC1 I S1 ⎝ ⎠ ⎛ ∆I ⎞ ⎛ ∆I ⎞ I +I ∆I S = I S1 − I S 2 | I S = S1 S 2 | I S1 = I S ⎜1+ S ⎟ | I S 2 = I S ⎜1− S ⎟ 2 ⎝ 2I S ⎠ ⎝ 2I S ⎠ ⎡ ⎛ ∆I ⎞ ⎤ ⎢ I S ⎜1+ S ⎟ ⎥ ⎤ ⎡ ⎛ IC 2 I S1 ⎞ ⎢ 1 ⎝ 2I S ⎠ ⎥ = 0.025ln⎢ (1.05)⎥ = 2.50 mV I = I : ∆V = V ln a = 0.025ln ⎜ ⎟ ( ) C 2 C1 BE T ⎢() ⎛ ∆I S ⎞ ⎥ ⎝ IC1 I S 2 ⎠ ⎢⎣(0.95)⎥⎦ ⎟⎥ ⎢ I S ⎜1− ⎝ 2I S ⎠ ⎦ ⎣ ⎡ (1.10)⎤ (b) ∆VBE = 0.025ln⎢⎢ 0.90 ⎥⎥ = 5.02 mV )⎦ ⎣( ⎛ ∆I S ⎞ ⎜1+ ⎟ ⎛V − V ⎞ ⎛ 0.001⎞ IS ⎠ ∆I I S1 ⎝ (c) I = ⎛ ∆I ⎞ = exp⎜⎝ BE2V BE1 ⎟⎠ = exp⎜⎝ 0.025⎟⎠ = 1.04 → I S = 0.02 or 2% S2 T S S ⎜1− ⎟ IS ⎠ ⎝ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-81 15.130 (a) For v1 = 0 = v2 , VBE1 = VBE 2 and the collector currents are the same. So, VOS = 0. Only the base currents will be mismatched. ⎛ VBE ⎞⎛ VCE ⎞ ⎛ VBE ⎞⎛ VCE ⎞ 1 + | I I = I 1− 0.025 exp = I 1+ 0.025 exp b ⎜ ⎟ ⎜ ⎟ ( ) C1 S ( ) ⎝ V ⎠⎝ V ⎠ C 2 S ( ) ⎜⎝ V ⎟⎠⎜⎝1 + V ⎟⎠ T A T A ⎛ V ⎞⎛ V ⎞ ⎛ V ⎞⎛ V ⎞ I +I ∆IC = IC 2 − IC1 = 0.05I S exp⎜ BE ⎟⎜1 + CE ⎟ | IC = C1 C 2 = I S exp⎜ BE ⎟⎜1 + CE ⎟ VA ⎠ 2 VA ⎠ ⎝ VT ⎠⎝ ⎝ VT ⎠⎝ ∆I ∆I VOS = C = VT C = 0.025V (0.05)= 1.25 mV gm IC ⎞ ⎞ ⎛ VBE ⎞⎛ ⎛ VBE ⎞⎛ VCE VCE ⎜ ⎟ ⎜ c 1 + 1 + I = I exp = I exp | I ( ) C1 S ⎜⎝ V ⎟⎠⎜ V 1+ 0.025 ⎟ C 2 S ⎜⎝ V ⎟⎠⎜ V 1− 0.025 ⎟⎟ )⎠ )⎠ T ⎝ T ⎝ A( A( ⎛ V ⎞⎛ ⎛ V ⎞⎛ V V ⎞ V ⎞ ∆IC = IC 2 − IC1 ≅ I S exp⎜ BE ⎟⎜1-1.025 CE −1+ 0.975 CE ⎟ = I S exp⎜ BE ⎟⎜0.05 CE ⎟ VA VA ⎠ VA ⎠ ⎝ VT ⎠⎝ ⎝ VT ⎠⎝ ⎛ VCE ⎞ ⎜ ⎟ ⎛ VBE ⎞⎛ VCE ⎞ IC1 + IC 2 ∆IC ∆IC ⎝ VA ⎠ IC = = I S exp⎜ = VT = 0.025V (0.05) ⎟⎜1 + ⎟ | VOS = ⎛ VCE ⎞ 2 VA ⎠ gm IC ⎝ VT ⎠⎝ ⎜1 + ⎟ VA ⎠ ⎝ V For CE = 0.1, VOS = 114 µV VA (d ) V OD VOS = [ ] = IC (RC + 0.025RC )− (RC − 0.025RC ) = 0.05IC RC VOD V = VT OD = 0.025V (0.05) = 1.25 mV g m RC IC RC 15.131 ⎛V ⎞ ⎛ V + 0.002 ⎞ IS1 ⎛ 0.002 ⎞ IS1 exp⎜ BE1 ⎟ = IS 2 exp⎜ BE1 = exp⎜ ⎟ = 1.08 | IS1 = 1.08IS 2 ⎟ | ⎝ 0.025 ⎠ VT ⎝ VT ⎠ ⎝ ⎠ IS 2 I +I ∆IS 0.08 ∆IS = IS1 − IS 2 = 0.08IS 2 | IS = S1 S 2 = 1.04IS 2 | = = 7.7% 2 IS 1.04 ⎛ 10V ⎞ ⎛ 10V ⎞ β F1 = 100(1+ 0.025)⎜1+ ⎟ = 123 | β F 2 = 100(1− 0.025)⎜1+ ⎟ = 117 ⎝ 50V ⎠ ⎝ 50V ⎠ 100µA 100µA IB1 = = 0.813 µA | IB 2 = = 0.855 µA 123 117 Note: IOS = -42.0 nA. 15-82 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.132 (a) ID = (250)(1± 0.05) µA 2 [2 − (1± 0.025)] 2 | IDmax = (250)(1+ 0.05) µA 2 [1+ 0.025] V V 2 2 (250)(1− 0.05) µA 1− 0.025 2 = 113µA IDmin = [ ] 2 V2 138µA +113µA ∆ID = 125.5µA | ∆ID = 138µA −113µA = 25µA | = 19.8% ID = ID 2 (b) IDmax = (250)(1+ 0.05) µA 2 =138µA [3 + 0.025] 2 =1.20mA V 2 (250)(1− 0.05) µA 3 − 0.025 2 = 1.05mA IDmin = [ ] 2 V2 1.20mA +1.05mA ∆ID = 1.125mA | ∆ID = 1.20mA −1.05mA = 0.150mA | = 13.3% ID = ID 2 15.133 VGS1 = VTN + VGS 2 = VTN + 2 1 2IDS1 2IDS1 2IDS1 ⎛ ∆ (W /L)⎞ = VTN + ≅ VTN + ⎜1− ⎟ ⎛W ⎞ ⎛W ⎞ ⎛W ⎞ ∆ (W /L) 4 (W /L) ⎠ K n' ⎜ ⎟ K n' ⎜ ⎟ 1+ K n' ⎜ ⎟ ⎝ ⎝ L ⎠1 ⎝L⎠ ⎝L⎠ 2(W /L) 1 2IDS 2 2IDS 2 2IDS 2 ⎛ ∆ (W /L)⎞ = VTN + ≅ VTN + ⎜1+ ⎟ ∆ (W /L) 4 (W /L) ⎠ ' ⎛W ⎞ ' ⎛W ⎞ ' ⎛W ⎞ ⎝ Kn ⎜ ⎟ K n ⎜ ⎟ 1− Kn ⎜ ⎟ ⎝ L ⎠2 ⎝L⎠ ⎝L⎠ 2(W /L) IDS 2 = IDS1 : VGS 2 − VGS1 = ⎛ ∆ (W /L)⎞ 2IDS 2 ⎛ ∆ (W /L)⎞ ⎜ ⎟ = (VGS − VTN )⎜ ⎟ 2(W /L) ⎠ ' ⎛ W ⎞ ⎝ 2(W /L ) ⎠ ⎝ Kn⎜ ⎟ ⎝L⎠ ⎛ ∆ (W /L)⎞ ⎛ 0.10 ⎞ ⎟ = (0.5)⎜ ⎟ = 25 mV ⎝ 2 ⎠ ⎝ 2(W /L ) ⎠ (a) ∆VGS = (VGS − VTN )⎜ (b) ∆ (W /L) ∆VGS 0.003 =2 =2 = 1.2 % | 0.5 (W /L) (VGS − VTN ) (c ) ∆ (W /L ) ∆VGS 0.001 =2 =2 = 0.4 % 0.5 (W /L) (VGS − VTN ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-83 15.134 ⎡⎛ W ⎞ ⎛ W ⎞ ⎤ K ' 2 ∆ID = ID 2 − ID1 = ⎢⎜ ⎟ − ⎜ ⎟ ⎥ n (VGS − VTN ) (1+ λVDS ) ⎣⎝ L ⎠ 2 ⎝ L ⎠1⎦ 2 ⎛ 0.05 ⎞ ∆I ∆I ∆ID = 0.05ID | VOS = D = (VGS − VTN ) D = 0.75V ⎜ ⎟ = 18.8 mV ⎝ 2 ⎠ gm 2ID K 2 2 (b) ∆ID = ID 2 − ID1 = n (1+ λVDS ) (VGS − VTN + 0.025VTN ) − (VGS − VTN − 0.025VTN ) 2 ID K ∆ID = n (1+ λVDS )(0.1VTN )(VGS − VTN ) = (0.1VTN ) 2 (VGS − VTN ) (a) Assume active region operation : [ ] ∆I ∆ID = (VGS − VTN ) D = 0.05 VTN | If VTN = 1V, VOS = 50 mV gm 2ID K 2 (c ) ∆ID = ID 2 − ID1 = n (VGS − VTN ) [(1+ λVDS + 0.025 λVDS ) − (1+ λVDS − 0.025 λVDS )] 2 ⎛ 0.05 ⎞⎛ λVDS ⎞ 0.05 λVDS ∆I ∆I ∆ID = ID 2 − ID1 = ID | VOS = D = (VGS − VTN ) D = 0.75V ⎜ ⎟⎜ ⎟ ⎝ 2 ⎠⎝ 1+ λVDS ⎠ 1+ λVDS gm 2ID VOS = If λVDS = 0.1, VOS = 1.71 mV (d) VOD = ID [(RD + 0.025RD ) − (RD − 0.025RD )] = 0.05ID RD VOS = VOD V 0.05ID = OD = (VGS − VTN ) = 0.025(0.75V ) = 18.8 mV Avt gm RD 2ID 15.135 (a) I OX ⎛W ⎞ ⎜ ⎟ 1+ λVDSX ⎝ L ⎠X = I ⎛ W ⎞ REF 1+ λVDS1 ⎜ ⎟ ⎝ L ⎠1 1 | RoutX ( ( = λ + VDSX IOX ) ) 2 30x10−6 2I D1 VDS1 = VGS1 = VTN + = 0.75 + = 1.52V Kn 4 25x10−6 1 + 10 10 0.015 IO2 = (30µA) = 84.3µA | Rout2 = = 909kΩ 84.3µA 4 1+ 0.015(1.52) 1+ 0.015(10) 1 +8 20 0.015 = 164µA | Rout3 = = 455kΩ IO3 = (30µA) 164µA 4 1+ 0.015(1.52) 1+ 0.015(8) 1 + 12 40 0.015 = 346µA | Rout 4 = = 227kΩ IO 4 = (30µA) 346µA 4 1+ 0.015(1.52) 1+ 0.015(12) 15-84 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.135 cont. ⎛W ⎞ ⎜ ⎟ L 1+ λV (b) IOX = ⎝⎛W⎠⎞X I REF 1+ λVDSX DS1 ⎜ ⎟ ⎝ L ⎠1 1 | RoutX = λ ( ( + VDSX IOX ) ) 2 50x10−6 2I D1 VDS1 = VGS1 = VTN + = 0.75 + = 1.75V Kn 4 25x10−6 1 + 10 10 IO2 = (50µA) = 140µA | Rout2 = 0.015 = 548kΩ 140µA 4 1+ 0.015(1.75) 1+ 0.015(10) 1 +8 20 IO3 = (50µA) = 273µA | Rout3 = 0.015 = 274kΩ 273µA 4 1+ 0.015(1.75) 1+ 0.015(8) 1 + 12 1+ 0.015(12) 40 = 575µA | Rout 4 = 0.015 = 137kΩ IO 4 = (50µA) 575µA 4 1+ 0.015(1.75) (c) I O2 IO 4 = = 40 (30µA)= 300 µA | Rout 4 = ∞ 4 15.136 (a) I OX ⎛W ⎞ ⎜ ⎟ 1+ λVDSX ⎝ L ⎠X = I REF ⎛W ⎞ 1+ λVDS1 ⎜ ⎟ ⎝ L ⎠1 ( ( ) ) 2 30x10−6 2I D1 | VDS1 = VGS1 = VTN + = 0.75 + = 1.73V Kn 2.5 25x10−6 1+ 0.015(10) 1+ 0.015(8) 10 20 30µA) = 135 µA | IO3 = 30µA) = 262 µA ( ( 2.5 2.5 1+ 0.015(1.73) 1+ 0.015(1.73) IO2 = IO 4 = (b) V 1+ 0.015(12) 40 30µA) = 552 µA ( 2.5 1+ 0.015(1.73) DS1 IO3 = 10 20 30µA) = 75 µA | Rout2 = ∞ | IO3 = (30µA)= 150 µA | Rout3 = ∞ ( 4 4 = 0.75 + ( ) = 1.27V 6(25x10 ) 2 20x10−6 −6 | IO2 = 1+ 0.015(10) 10 20µA) = 37.6 µA ( 6 1+ 0.015(1.27) 1+ 0.015(8) 1+ 0.015(12) 20 40 20µA) = 73.3 µA | IO 4 = (20µA) = 154 µA ( 6 6 1+ 0.015(1.27) 1+ 0.015(1.27) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-85 15.137 (a) For λ = 0, I O2 ⎛ 10 ⎞ ⎛ 20 ⎞ ⎛ 40 ⎞ = 30µA⎜ ⎟ = 75µA, IO3 = 30µA⎜ ⎟ = 150µA, IO2 = 30µA⎜ ⎟ = 300µA ⎝4⎠ ⎝4⎠ ⎝4⎠ (b) From Prob. 16.8, I O2 = 84.3µA, IO3 = 164µA, IO 4 = 346µA ∆IO2 84.3 − 75 ∆IO3 164 −150 ∆IO 4 346 − 300 = = 0.124 LSB, = = 0.187 LSB, = = 0.613 LSB IO2 IO2 IO2 75 75 75 15.138 *Problem 15.135(a) - NMOS Current Source Array IREF 0 1 DC 30U VD2 2 0 DC 10 AC 1 VD3 3 0 DC 8 AC 1 VD4 4 0 DC 12 AC 1 M1 1 1 0 0 NFET W=4U L=1U M2 2 1 0 0 NFET W=10U L=1U M3 3 1 0 0 NFET W=20U L=1U M4 4 1 0 0 NFET W=40U L=1U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.015 .OP .AC LIN 1 1000 1000 .PRINT AC IM(VD2) IM(VD3) IM(VD4) IP(VD2) IP(VD3) IP(VD4) .END The results are identical to the hand calculations. 15.139 2 5 + VGS 1 15x10-6 ⎛ 2 ⎞ 5 + VGS 1 I D1 = | → VGS 1 = −2.985V ⎜ ⎟(VGS 1 + 0.9) (1− 0.01VGS 1 )= R 2 ⎝ 1⎠ 3x10 4 I REF = 5 − 2.985 = 67.2µA 3x10 4 1 + VDS 2 2 15x10-6 ⎛ 8 ⎞ 100 + 5 λ IO2 = = = 383kΩ ⎜ ⎟(−2.985 + 0.9) 1− 0.01(−5) = 274µA | Rout 2 = 274µA 2 ⎝ 1⎠ IO 2 2 15x10-6 ⎛16 ⎞ 100 + 10 = 192kΩ IO3 = ⎜ ⎟(−2.985 + 0.9) 1− 0.01(−10) = 574µA | Rout 3 = 574µA 2 ⎝1⎠ [ [ 15-86 ] ] ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.140 5 + VGS1 15x10-6 ⎛ 3.3 ⎞ 5 + VGS 1 2 | → VGS 1 = −2.655V ⎜ ⎟(VGS 1 + 0.9)1 (1− 0.01VGS 1 )= R 2 ⎝ 1 ⎠ 3x10 4 2 5 − 2.655 15x10-6 ⎛ 8 ⎞ = 78.2 µ A | I = I REF = ⎜ ⎟(−2.655 + 0.9) 1− 0.01(−5) = 194µA O2 4 2 ⎝1⎠ 3x10 -6 ⎛ 2 15x10 16 ⎞ IO3 = ⎜ ⎟(−2.655 + 0.9) 1− 0.01(−10) = 407µA 2 ⎝1⎠ 5+V 15x10-6 ⎛ 4 ⎞ 5+V (b) I D1 = R GS1 | 2 ⎜⎝ 1 ⎟⎠(VGS1 + 0.9)12 (1− 0.01VGS1)= 5x10GS41 → VGS1 = −2.241V 2 5 − 2.241 15x10-6 ⎛ 8 ⎞ = 55.2 µ A | I = I REF = ⎜ ⎟(−2.241+ 0.9) 1− 0.01(−5) = 113µA O2 4 2 ⎝1⎠ 3x10 2 15x10-6 ⎛16 ⎞ IO3 = ⎜ ⎟(−2.241+ 0.9) 1− 0.01(−10) = 237µA 2 ⎝1⎠ (a) I D1 = [ [ ] [ ] ] [ ] 15.141 *Problem 15.141 - PMOS Current Source Array RREF 0 1 30K VSS 4 0 DC 5 VD2 2 0 DC 0 AC 1 VD3 3 0 DC -5 AC 1 M1 1 1 4 4 PFET W=2U L=1U M2 2 1 4 4 PFET W=8U L=1U M3 3 1 4 4 PFET W=16U L=1U .MODEL PFET PMOS KP=15U VTO=-0.9 LAMBDA=0.01 .OP .AC LIN 1 1000 1000 .PRINT AC IM(VD2) IM(VD3) IP(VD2) IP(VD3) .END The results are identical to the hand calculations. 15.142 K ' ⎛W ⎞ 2 2 15x10-6 ⎛ 8 ⎞ I D2 = p ⎜ ⎟(VGS 2 − VTP ) 1+ λ VDS 2 | 55x10-6 = ⎜ ⎟(VGS1 + 0.9) 1+ 0.01−5 2 ⎝ L⎠ 2 ⎝ 1⎠ ⎛W ⎞ ⎛ 8⎞ ⎜ ⎟ 1+ λ VDS 2 ⎜ ⎟ 1+ 0.01(5) I D2 ⎝ L ⎠2 55µA ⎝ 1 ⎠2 VGS1 = −1.834V | = | = → I REF = 13.3µA ⎛ 2⎞ I REF I REF ⎛W ⎞ ⎜ ⎟ 1+ λ VDS1 ⎜ ⎟ 1+ 0.01(1.834) ⎝ L ⎠1 ⎝ 1 ⎠1 5 + VGS1 5 −1.834 I REF = | R= = 238 kΩ R 13.3µA [ ] [ [ ] [ ] [ [ ] ] ] 15.143 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-87 (a) I REF = ⎛ V ⎞⎛ 14.3 VBE ⎞ 12 − 0.7 = 151 µA | I REF = IC1 + (1+ 5 + 8.3)I B | I REF = I S exp⎜ BE ⎟⎜1+ + ⎟ 4 7.5x10 ⎝ VT ⎠⎝ β FO VA ⎠ V 5 1+ CE 2 1+ ⎛ VBE ⎞⎛ VCE2 ⎞ VA 60 IO2 = 5I S exp⎜ | IO2 = 5(151µA) = 631 µA ⎟⎜1+ ⎟ = 5I REF 14.3 VBE 14.3 0.7 VA ⎠ ⎝ VT ⎠⎝ 1+ + 1+ + β FO VA 50 60 VA + VCE2 60 + 5 = = 103 kΩ IC 2 6.31x10−4 V 3 1+ CE 3 1+ VA 60 IO3 = 8.3I REF = 8.3(151µA) = 1.02 mA 14.3 VBE 14.3 0.7 1+ + 1+ + β FO VA 50 60 Rout2 = ro2 = Rout3 = ro3 = VA + VCE3 60 + 3 = = 61.8 kΩ IC 3 1.02x10−3 (b) Since all areas are scaled equally, the current ratios stay the same, and there is no change from part (a). This ignores the slight change in VBE of Q1 due to its area change. I 12 − 0.7 − 0.7 = 141 µA | I REF = IC1 + (1+ 5 + 8.3) B 4 β FO + 1 7.5x10 ⎛ V ⎞⎛ 2V ⎞ 14.3 I REF = I S exp⎜ BE ⎟⎜⎜1+ + BE ⎟⎟ ⎝ VT ⎠⎝ β FO (β FO + 1) VA ⎠ V 1+ CE 2 ⎛ VBE ⎞⎛ VCE2 ⎞ VA IO2 = 5I S exp⎜ ⎟⎜1+ ⎟ = 5I REF 14.3 2V VA ⎠ ⎝ VT ⎠⎝ 1+ + BE β FO (β FO + 1) VA (c) I REF = 5 V + VCE2 60V + 5V 60 IO2 = 5(141µA) = 745 µA | Rout2 = ro2 = A = = 87.2 kΩ 14.3 1.4 IC 2 745µA 1+ + 50(51) 60 1+ VCE3 3 1+ VA 60 IO3 = 8.3I REF = 8.3(141µA) = 1.20 mA 14.3 2VBE 14.3 1.4 1+ + 1+ + 50(51) 60 β FO (β FO + 1) VA 1+ Rout3 = ro3 = 15-88 VA + VCE3 60V + 3V = = 52.5 kΩ IC 3 1.20mA ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.144 *Problem 15.144 – Figure P15.143(a) - NPN Current Source Array RREF 2 1 75K VCC 2 0 DC 12 VC2 3 0 DC 5 AC 1 VC3 4 0 DC 3 AC 1 Q1 1 1 0 NBJT 1 Q2 3 1 0 NBJT 5 Q3 4 1 0 NBJT 8.3 .MODEL NBJT NPN BF=50 VA=60 .OP .AC LIN 1 1000 1000 .PRINT AC IM(VC2) IM(VC3) IP(VC2) IP(VC3) .END *Problem 15.144 – Figure 15.143(b) - Buffered NPN Current Source Array RREF 2 5 75K VCC 2 0 DC 12 VC2 3 0 DC 5 AC 1 VC3 4 0 DC 3 AC 1 Q1 5 1 0 NBJT 1 Q2 3 1 0 NBJT 5 Q3 4 1 0 NBJT 8.3 Q4 2 5 1 NBJT 1 .MODEL NBJT NPN BF=50 VA=60 .OP .AC LIN 1 1000 1000 .PRINT AC IM(VC2) IM(VC3) IP(VC2) IP(VC3) .END The results are almost identical to the hand calculations. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-89 15.145 ⎛ VBE ⎞⎛ 14.3 VBE ⎞ = I + 1+ 5 + 8.3 I = I + 14.3I = I exp + ⎜ ⎟⎜1+ ⎟ ( ) REF C1 B C1 B S ⎝ VT ⎠⎝ β FO VA ⎠ ⎛ V ⎞⎛ 14.3 0.7 ⎞ ⎛ VBE ⎞ + I REF ≅ I S exp⎜ BE ⎟⎜1+ ⎟ ⎟ = 1.298I S exp⎜ 50 60 ⎠ ⎝ VT ⎠⎝ ⎝ VT ⎠ V 1+ CE2 ⎛ VBE ⎞⎛ VCE3 ⎞ 150µA(1.298) VA IO3 = 8.3I S exp⎜ | I REF = = 22.3µA ⎟⎜1+ ⎟ = 8.3I REF ⎛ VA ⎠ 1.298 3⎞ ⎝ VT ⎠⎝ 8.3⎜1+ ⎟ ⎝ 60 ⎠ V 5 1+ CE2 1+ 12 − 0.7 12 − 0.7 VA I REF = | R= = 507 kΩ | IO2 = 5I REF = 5(22.3µA) 60 = 93.1 µA R 22.3µA 1.298 1.298 ⎛ VBE ⎞⎛ 14.3 14.3I B 2VBE ⎞ IB ⎜ b 1+ I = I + 1+ 5 + 8.3 = I + = I exp + ( ) REF C1 ( )β + 1 C1 β + 1 S ⎜⎝ V ⎟⎠⎜ β β + 1 V ⎟⎟ ) A⎠ FO FO T ⎝ FO ( FO ⎛ V ⎞⎛ ⎛V ⎞ 14.3 1.4 ⎞ ⎟ = 1.029I S exp⎜ BE ⎟ + I REF ≅ I S exp⎜ BE ⎟⎜⎜1+ ⎝ VT ⎠⎝ 50(51) 60 ⎟⎠ ⎝ VT ⎠ (a) I V 1+ CE2 ⎛ VBE ⎞⎛ VCE3 ⎞ VA IO3 = 8.3I S exp⎜ ⎟⎜1+ ⎟ = 8.3I REF VA ⎠ 1.029 ⎝ VT ⎠⎝ I REF 150µA(1.029) = 17.7µA ⎛ 3⎞ 8.3⎜1+ ⎟ ⎝ 60 ⎠ V 5 1+ CE2 1+ 12 − 0.7 − 0.7 12 −1.4 VA = | R= = 599 kΩ | IO2 = 5I REF = 5(17.7µA) 60 = 93.2 µA R 17.7µA 1.029 1.029 15-90 | I REF = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.146 (a) I REF = ⎛ VBE ⎞⎛ 7.65 VBE ⎞ ⎛ 5 8.3 ⎞ 12 − 0.7 = 151 µA | I REF = IC1 + ⎜1+ + + ⎟⎜1+ ⎟ ⎟ I B | I REF = I S exp⎜ 3 75x10 ⎝ 2 2 ⎠ ⎝ VT ⎠⎝ β FO VA ⎠ V 5 1+ CE2 1+ ⎛ ⎞ ⎛ ⎞ VCE2 5 VBE VA 75 IO2 = I S exp⎜ | IO2 = 2.5(151µA) = 376 µA ⎟⎜1+ ⎟ = 2.5I REF 7.65 VBE 7.65 0.7 VA ⎠ 2 ⎝ VT ⎠⎝ 1+ + 1+ + β FO VA 125 75 VCE3 3 1+ 8.3 VA 75 IO3 = I REF = 4.15(151µA) = 609 µA 7.65 VBE 7.65 0.7 2 1+ + 1+ + β FO VA 125 75 ⎛ 5 8.3 ⎞ I 12 − 0.7 − 0.7 (b) I REF = 75x104 = 141 µA | I REF = IC1 + ⎜⎝1+ 2 + 2 ⎟⎠ β B+ 1 FO ⎛ V ⎞⎛ 2V ⎞ 7.65 I REF = I S exp⎜ BE ⎟⎜⎜1+ + BE ⎟⎟ ⎝ VT ⎠⎝ β FO (β FO + 1) VA ⎠ V 1+ CE2 ⎛ ⎞ ⎛ ⎞ 5 V V VA IO2 = I S exp⎜ BE ⎟⎜1+ CE2 ⎟ = 2.5I REF 7.65 2V VA ⎠ 2 ⎝ VT ⎠⎝ 1+ + BE β FO (β FO + 1) VA 1+ 5 75 IO2 = 2.5(141µA) = 370 µA 7.65 1.4 1+ + 125(126) 75 1+ VCE3 3 1+ 8.3 VA 75 I REF = 4.15(141µA) = 596 µA IO3 = 7.65 2VBE 6.65 1.4 2 1+ + 1+ + β FO (β FO + 1) VA 125(126) 75 1+ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-91 15.147 ⎛ 5 8.3⎞ I B 12 − 0.7 − 0.7 = 106 µ A | I = I + 1+ + ⎜ ⎟ REF C1 100x103 ⎝ 3 3 ⎠ β FO + 1 ⎛ V ⎞⎛ 2V ⎞ 5.43 I REF = I S exp⎜ BE ⎟⎜⎜1+ + BE ⎟⎟ ⎝ VT ⎠⎝ β FO (β FO + 1) VA ⎠ V 1+ CE 2 ⎛ ⎞ ⎛ ⎞ V 5 5 V VA IO2 = I S exp⎜ BE ⎟⎜1+ CE 2 ⎟ = I REF 5.43 2V VA ⎠ 3 3 ⎝ VT ⎠⎝ 1+ + BE β FO (β FO + 1) VA I REF = 5 IO2 = (106µA) 3 1+ 5 75 = 185 µA 5.43 1.4 + 100(101) 75 1+ VCE 3 3 1+ 8.3 8.3 VA I REF = IO3 = (106µA) 5.4375 1.4 = 299 µA 5.43 2VBE 3 3 1+ + 1+ + 100(101) 75 β FO (β FO + 1) VA 1+ 15-92 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.148 (a) I REF = ⎛ VBE ⎞⎛ 14.3 VBE ⎞ 12 − 0.7 = 80.7 µ A | I = I + 1+ 5 + 8.3 I | I = I exp + ⎟ ⎜ ⎟⎜1+ ( ) REF C1 B REF S 1.4x105 ⎝ VT ⎠⎝ β FO VA ⎠ VCE 2 5 1+ ⎛ V ⎞⎛ V ⎞ V 75 A IO2 = 5I S exp⎜ BE ⎟⎜1+ CE2 ⎟ = 5I REF | IO2 = 5(80.7µA) = 383 µA 14.3 VBE 14.3 0.7 VA ⎠ ⎝ VT ⎠⎝ 1+ + 1+ + 125 75 β FO VA 1+ VCE 3 3 1+ VA 75 IO3 = 8.3I REF = 8.3(80.7µA) = 620 µA 14.3 VBE 14.3 0.7 1+ + 1+ + 125 75 β FO VA ⎛ VBE ⎞⎛ IB 14.3I B 2VBE ⎞ 14.3 ⎜ (b) I REF = IC1 + (1+ 5 + 8.3)β + 1 = IC1 + β + 1 = I S exp⎜⎝ V ⎟⎠⎜1+ β β + 1 + V ⎟⎟ ) A⎠ FO FO T ⎝ FO ( FO ⎛ V ⎞⎛ ⎛V ⎞ 1.4 ⎞ 14.3 ⎟ = 1.029I S exp⎜ BE ⎟ + I REF = I S exp⎜ BE ⎟⎜⎜1+ ⎝ VT ⎠⎝ 125(126) 75 ⎟⎠ ⎝ VT ⎠ V 1+ CE 2 ⎛ V ⎞⎛ V ⎞ 620µA(1.02) VA | I REF = = 73.3µA IO3 = 8.3I S exp⎜ BE ⎟⎜1+ CE3 ⎟ = 8.3I REF ⎛ VA ⎠ 1.02 3⎞ ⎝ VT ⎠⎝ 8.3⎜1+ ⎟ ⎝ 75 ⎠ 1+ 12 − 0.7 − 0.7 12 −1.4 | R= = 145 kΩ R 73.3µA V 5 1+ CE 2 1+ VA = 5(73.3µA) 75 = 383 µA - Correct. Checking : IO2 = 5I REF 1.02 1.02 I REF = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-93 15.149 Use βFO = 50 and VA = 60 V. (a) I REF = ⎛ V ⎞⎛ 14.3 VBE ⎞ 12 − 0.7 = 113 µA | I REF = IC1 + (1+ 5 + 8.3)I B | I REF = I S exp⎜ BE ⎟⎜1+ + ⎟ 5 10 ⎝ VT ⎠⎝ β FO VA ⎠ V 5 1+ CE 2 1+ ⎛ VBE ⎞⎛ VCE2 ⎞ VA 60 IO2 = 5I S exp⎜ | IO2 = 5(113µA) = 472 µA ⎟⎜1+ ⎟ = 5I REF 14.3 VBE 14.3 0.7 VA ⎠ ⎝ VT ⎠⎝ 1+ + 1+ + β FO VA 50 60 VCE 3 3 1+ VA 60 IO3 = 8.3I REF = 8.3(113µA) = 759 µA 14.3 VBE 14.3 0.7 1+ + 1+ + β FO VA 50 60 1+ 6 (b) IO2 = 5(113µA) 14.360 0.7 = 479 µA | No change in IO3. 1+ + 50 60 11− 0.7 (c) I REF = 105 = 103 µA | IO2 and IO3 are proportional to I REF 103µA 103µA IO2 = 472µA = 430 µA | IO3 = 472µA = 430 µA 113µA 113µA 1+ 103µA = 692 µA 113µA 60 + 5 ∆V 1V = = 138kΩ | ∆IO2 = = = 7.25µA 472µA ro2 138kΩ IO3 ∝ I REF | IO2 = 759µA (d ) R out2 = ro2 = VA + VCE2 IC 2 IO2−6V − IO2−5V = 479µA − 472µA = 7µA - Agrees within the calculation precision. 15.150 I REF = ⎛ V ⎞ 15 − 0.7 = 238µA | I REF = 2IC 1 + (2 + 1+ 6 + 9)I B = 2β FO ⎜1+ EC1 ⎟ I B + 18I B 4 VA ⎠ 6x10 ⎝ 238µA = 2.00µA ⎛ 0.7 ⎞ 18 + 2(50)⎜1+ ⎟ ⎝ 60 ⎠ ⎛ V ⎞ ⎛ 15 ⎞ 60 + 15 IO2 = β FO ⎜1+ EC 2 ⎟ I B = 50⎜1+ ⎟(2.00µA) = 125µA | Rout 2 = ro2 = = 600 kΩ VA ⎠ 1.25x10−4 ⎝ 60 ⎠ ⎝ ⎛ V ⎞ ⎛ 9⎞ 60 + 9 = 100 kΩ IO3 = 6β FO ⎜1+ EC 3 ⎟ I B = 300⎜1+ ⎟(2.00µA) = 690µA | Rout 3 = ro3 = VA ⎠ 6.90x10−4 ⎝ 60 ⎠ ⎝ ⎛ V ⎞ ⎛ 27 ⎞ 60 + 27 = 66.4 kΩ IO 4 = 9β FO ⎜1+ EC 4 ⎟ I B = 450⎜1+ ⎟(2.00µA)= 1.31mA | Rout 4 = ro 4 = VA ⎠ 1.31x10−3 ⎝ 60 ⎠ ⎝ IB = 15-94 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.151 ⎛ V ⎞ 15 − 0.7 = 238µA | I REF = 2IC 1 + (2 + 1+ 6 + 9)I B = 2β FO ⎜1+ EC1 ⎟ I B + 18I B VA ⎠ R ⎝ ⎡ ⎛ VEC 3 ⎞ ⎛ 0.7 ⎞⎤ 65µA = I B ⎢18 + 2(50)⎜1+ = 0.189µA ⎟IB | IB = ⎟⎥ = 119I B | IO3 = 6β FO ⎜1+ ⎛ VA ⎠ 9⎞ ⎝ 60 ⎠⎦ ⎝ ⎣ 300⎜1+ ⎟ ⎝ 60 ⎠ I REF = I REF 15 − 0.7 = 63.8 kΩ 22.4µA ⎛ V ⎞ ⎛ 15 ⎞ IO2 = β FO ⎜1+ EC 2 ⎟ I B = 50⎜1+ ⎟(0.189µA)= 11.8 µA VA ⎠ ⎝ 60 ⎠ ⎝ ⎛ V ⎞ ⎛ 27 ⎞ IO 4 = 9β FO ⎜1+ EC 4 ⎟ I B = 450⎜1+ ⎟(0.189µA)= 123 µA VA ⎠ ⎝ 60 ⎠ ⎝ I REF = 119I B = 22.4µA | R = 15.152 15 V 2A Q 1 9A Q Q A Q R 6A A Q 3 2 4 5 I O2 I O4 I O3 +6 V -12 V (2 + 1+ 6 + 9)I B 15V − 0.7V − 0.7V = 544kΩ | I REF = IC1 + 25µA β FO + 1 ⎛ V ⎞ 18I B 25µA I REF = 2β FO ⎜1+ EC1 ⎟ I B + | IB = = 0.2435µA ⎛ VA ⎠ β FO + 1 1.4 ⎞ 18 ⎝ 2(50)⎜1+ ⎟+ ⎝ 60 ⎠ 51 ⎛ V ⎞ ⎛ 15 ⎞ IO2 = β FO ⎜1+ EC 2 ⎟ I B = 50⎜1+ ⎟ I B = 15.2 µA VA ⎠ ⎝ 60 ⎠ ⎝ ⎛ V ⎞ ⎛ 9⎞ IO3 = 6β FO ⎜1+ EC 3 ⎟ I B = 300⎜1+ ⎟ I B = 84.0 µA VA ⎠ ⎝ 60 ⎠ ⎝ ⎛ V ⎞ ⎛ 27 ⎞ 50 IO 4 = 9β FO ⎜1+ EC 4 ⎟ I B = 450⎜1+ ⎟ I B = 159 µA | IC 5 = α F I E 5 = 18I B = 4.30 µA VA ⎠ 51 ⎝ 60 ⎠ ⎝ R= ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-95 15.153 VBE2 + I E 2 R2 = VBE3 + I E 3 R3 → I E3 = R2 V −V I E 2 + BE2 BE 3 R3 R3 In order to have equal base - emitter voltages, the two transistors must operate at the equal collector − current densities : I E2 I E 3 5I E 2 = = → n = 10 2 A nA nA 15.154 ⎞ I I REF I I 76 ⎛ I = REF | I E1 = C1 = ⎜ REF ⎟ = REF 7 1.093 α F 75 ⎝1.093 ⎠ 1.079 1+ 75 I 12V - 0.7V 12 = I REF (10kΩ)+ 0.7V + REF (10kΩ) | I REF = = 586µA | I E1 = 543µA 1.079 10kΩ(1.927) I REF = IC1 + 7I B | IC1 ≅ 75 (543µA)= 1.07mA | VE1 = 543µA(10kΩ)= 5.43V 76 75 1 1 | IO3 = α F (4I E1 )= 4 (543µA) = 2.14mA | = = 46.6Ω 76 g m1 40(536µA) I E2 = 2I E1 | IO2 = α F (2I E1 )= 2 I E3 = 4I E1 ⎛ 1 ⎞ Rth = R ⎜ + R1 ⎟ = 10kΩ (46.6Ω + 10kΩ) = 5.01kΩ | Rth2 = Rth rπ 3 + (β o3 + 1)(2.5kΩ) ⎝ g m1 ⎠ [ rπ 2 = 75(0.025V ) 1.07mA = 1.75kΩ | rπ 3 = 75(0.025V ) [ 2.14mA = 0.876kΩ | ro2 = ] 60 + (10 − 5.43) ] Rth2 = 5.01kΩ 0.876kΩ + (76)(2.5kΩ) = 4.88kΩ 1.07mA = 60.4kΩ ⎛ ⎞ ⎛ ⎞ 75(5kΩ) β o R2 ⎟ = 2.01 MΩ Rout2 = ro2⎜1+ ⎟ = 60.4kΩ⎜⎜1+ ⎟ ⎝ Rth2 + rπ 2 + R2 ⎠ ⎝ 4.88kΩ + 1.75kΩ + 5kΩ ⎠ ro3 = (60 + 10 − 5.43)V = 30.2kΩ 2.14mA [ [ ] | Rth2 = Rth rπ 2 + (β o + 1)(5kΩ) ] Rth3 = 5.01kΩ 1.75kΩ + (76)(5kΩ) = 4.95kΩ ⎛ ⎞ ⎛ ⎞ 75(2.5kΩ) β o R3 ⎜ ⎟ = 30.2kΩ 1+ Rout3 = ro3⎜1+ ⎟ ⎜ 4.95kΩ + 0.876kΩ + 2.5kΩ ⎟ = 710 kΩ ⎝ Rth + rπ 3 + R3 ⎠ ⎝ ⎠ 15.155 For VBE2 = VBE 3, IO3 R3 = IO2 R2 | R3 = 15-96 IO2 I I 2 R2 = 3(5kΩ) = 15 kΩ | O2 = O3 | n = IO3 2 A nA 3 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.156 ⎞ I I REF I I 76 ⎛ I = REF | I E1 = C1 = ⎜ REF ⎟ = REF 13 1.173 α F 75 ⎝1.173 ⎠ 1.158 1+ 75 I 12V - 0.7V 12 = I REF (10kΩ)+ 0.7V + REF (20kΩ) | I REF = = 414µA | I E1 = 357µA 1.079 10kΩ(2.73) I REF = IC1 + 13I B | IC1 ≅ 75 (357µA)= 1.41 mA | VE1 = 357µA(20kΩ)= 7.14V 76 75 1 1 | IO3 = α F (8I E1 )= 8 (357µA)= 2.82 mA | = = 71.0Ω 76 g m1 40(352µA) I E2 = 4I E1 | IO2 = α F (4I E1 )= 4 I E3 = 8I E1 ⎛ 1 ⎞ Rth = R ⎜ + R1 ⎟ = 10kΩ (71.0Ω + 20kΩ)= 6.68kΩ | Rth2 = Rth rπ 3 + (β o3 + 1)(2.5kΩ) ⎝ g m1 ⎠ [ rπ 2 = 75(0.025V ) 1.41mA = 1.33kΩ | rπ 3 = 75(0.025V ) [ 2.82mA = 0.665kΩ | ro2 = ] 60 + (10 − 7.14) ] Rth2 = 6.68kΩ 0.665kΩ + (76)(2.5kΩ) = 6.45kΩ 1.41mA = 44.6kΩ ⎛ ⎞ ⎛ ⎞ 75(5kΩ) β o R2 ⎜ ⎟ = 1.35 MΩ Rout2 = ro2⎜1+ ⎟ = 44.2kΩ⎜1+ ⎟ 6.45kΩ + 1.33kΩ + 5kΩ ⎝ Rth2 + rπ 2 + R2 ⎠ ⎝ ⎠ ro3 = (60 + 10 − 7.14)V = 22.3kΩ 2.82mA [ [ ] | Rth2 = Rth rπ 2 + (β o + 1)(5kΩ) ] Rth3 = 6.68kΩ 1.33kΩ + (76)(5kΩ) = 6.57kΩ ⎛ ⎞ ⎛ ⎞ 75(2.5kΩ) β o R3 ⎜ ⎟ = 452 kΩ Rout3 = ro3⎜1+ ⎟ = 22.3kΩ⎜1+ ⎟ 6.57kΩ + 0.665kΩ + 2.5kΩ ⎝ Rth + rπ 3 + R3 ⎠ ⎝ ⎠ 15.157 IC1 = IREF = 15µA | IB = IC1 2ID | VCE1 = VBE1 + VGS 3 = 0.7 + VTN + ⎛ V ⎞ Kn β FO ⎜1+ CE1 ⎟ VA ⎠ ⎝ 15µA 4IB | VCE1 = 1.45 + | Solving iteratively yields IB = 0.147µA ⎛ VCE1 ⎞ 50x10−6 100⎜1+ ⎟ VA ⎠ ⎝ ⎛ V ⎞ ⎛ 5⎞ (75 + 5)V = 5.10 MΩ IO 2 = β FO ⎜1+ CE 2 ⎟ IB = 100⎜1+ ⎟(0.147µA) = 15.7 µA | Rout = ro2 = ⎝ 75 ⎠ 15.7µA VA ⎠ ⎝ ⎛ I 5⎞ Note : If one assumes IB ≅ C1 = 0.15µA, then IO 2 = 100⎜1+ ⎟(0.15µA) = 16.0 µA, a very ⎝ 75 ⎠ β FO IB = similar result and a valid approximation, since VCE1 << VA . ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-97 15.158 Results from SPICE were IC1 = 15.0 µA, IO = 15.7 µA and Rout = 5.06 MΩ. ELTOL VNTOL  an      results are very close to our hand calculations. Remember, SPICE uses ro3 =  These VA + VCB (75 + 4.3)V ≅ = 5.05 MΩ . 15.7µA IC 15.159 (a) R in = vref iref | v ref = (iref − g m1vbe1 )ro1 = iref ro1 − µ f 1vbe1 ( ) ⎡ g r r m3 π 1 π 2 vbe1 = v ref ⎢ ⎢1+ g m3 rπ 1 rπ 2 ⎣ ( ⎛ rπ 1 ⎞ ⎤ ⎟ ⎜ g m3 ⎞ ⎛ 2 ⎟ = v ⎜ g m3rπ 1 ⎟ ⎥≅v ⎜ ref r ⎥ ref ⎜ ⎝ 2 + g m3rπ 1 ⎠ ⎦ 1+ g m3 π 1 ⎟ ⎝ 2 ⎠ ) −1 1 ro1 1 1 ⎛ g m3rπ 1 ⎞ Rin = ≅ = ⎛ g m3rπ 1 ⎞ g m1 ⎛ g m3rπ 1 ⎞ g m1 ⎜⎝ 2 + g m3rπ 1 ⎟⎠ 1+ µ f 1⎜ ⎟ ⎟ ⎜ ⎝ 2 + g m3rπ 1 ⎠ ⎝ 2 + g m3rπ 1 ⎠ ( )( ) From Prob. 15.157, I D = 0.294µA, and g m3 = 2 50x10−6 0.294x10−6 = 5.42x10−6 S g m1 = 40(15µA)= 0.600mS Rin ≅ rπ 1 = ⎡2.905⎤ 1 ⎢ ⎥ = 5.35 kΩ 0.600mS ⎣0.905⎦ 100 = 167kΩ g m3rπ 1 = 0.905 0.600mS (b) SPICE yields Rin = 5.35 kΩ 15.160 ⎛I I ⎞ 10V − 0.7V − 0.7V = 860µA ≅ IC1 | IO2 R2 = VT ln⎜ C1 S 2 ⎟ 10kΩ ⎝ IO2 I S1 ⎠ ⎛ 860µA 2 ⎞ 10 4 IO2 = 0.025ln⎜ ⎟ → IO2 = 12.4 µA | VE 2 ≅ 12.4 µA(10kΩ)= 0.124V ⎝ IO2 1 ⎠ 60 + 5 − 0.124 ro2 = = 5.23 MΩ | Rth is small and the voltage across R2 is also small. 12.4µA I REF = [ ] Rout2 ≅ ro2 (1+ g m2 R2 )= 5.23MΩ 1+ 40(12.4 µA)(10kΩ) = 31.2 MΩ ⎛ 860µA 12 ⎞ 5x103 IO3 = 0.025ln⎜ ⎟ → IO3 = 29.3 µA | VE 3 ≅ 29.3 µA(5kΩ)= 0.147V ⎝ IO2 1 ⎠ 60 + 5 − 0.147 ro3 = = 2.21 MΩ | Rout3 ≅ ro3 (1+ g m3 R3 )= 2.21MΩ 1+ 40(0.147) = 15.2 MΩ 29.3µA [ 15-98 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ] 15.161 (10 − 0.7 − 0.7)V = 115kΩ | R = VT ln⎛ IREF IS 2 ⎞ = 0.025V ln⎛ 75µA 2 ⎞ = 17.0 kΩ R= ⎜ ⎟ ⎜ ⎟ 2 Io2 ⎝ IO 2 IS1 ⎠ 75µA 5µA ⎝ 5µA 1 ⎠ ⎛I ⎛ 75µA n ⎞ I ⎞ Io3 R3 = VT ln⎜ REF S 3 ⎟ | (10µA)(2kΩ) = 0.025V ln⎜ ⎟ → n = 0.297 ⎝ 10µA 1 ⎠ ⎝ IO 3 IS1 ⎠ 15.162 *Problem 15.162 - Buffered NPN Widlar Current Source Array RREF 1 3 115K VCC 1 0 DC 10 VC2 2 0 DC 5 AC 1 Q1 3 4 0 NBJT 1 Q2 2 4 5 NBJT 2 R2 5 0 17K Q3 2 4 6 NBJT 0.297 R3 6 0 2K Q4 1 3 4 NBJT 1 .MODEL NBJT NPN BF=100 VA=60 .OP .AC LIN 1 1000 1000 .PRINT AC IC(Q2) IC(Q3) .END Results: IC1 = 75.7 µA, IO2 = 5.18 µA, IO3 = 10.5 µA, ROUT2 = 53.4 MΩ ROUT3 = 11.1 MΩ 15.163 I REF = IO2 = ro2 = 5V − 0.7V − 0.7V − (−5V ) 40kΩ = 215µA ≅ IC1 | IO2 = VT ⎛ IC1 I S 2 ⎞ ln⎜ ⎟ R2 ⎝ IO2 I S1 ⎠ 0.025V ⎛ 215µA 10 ⎞ ln⎜ ⎟ → IO2 = 22.7 µA | VE 2 ≅ 22.7µA(5kΩ)= 0.114V 5kΩ ⎝ IO2 1 ⎠ 70 + 5 − 0.114 = 3.30 MΩ | Rth is small and the voltage across R2 is also small. 22.7µA [ ] Rout2 ≅ ro2 (1+ g m2 R2 )= ro2 (1+ 40IC 2 R2 ) = 3.30 MΩ 1+ 40(0.114) = 18.3 MΩ IO3 = ro3 = 0.025V ⎛ 215µA 20 ⎞ ln⎜ ⎟ → IO3 = 45.5 µA | VE 3 ≅ 45.4µA(2.5kΩ)= 0.114V 2.5kΩ ⎝ IO3 1 ⎠ 70 + 5 − 0.114 = 1.65MΩ | Rout3 ≅ ro3 (1+ g m3 R3 )= 1.65MΩ 1+ 40(0.114) = 9.17 MΩ 45.5µA [ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ] 15-99 15.164 5 − 0.7 − 0.7 − (−5) V = 172 kΩ R= 50µA I ⎞ 0.025V ⎛ 50µA 10 ⎞ V ⎛I R2 = T ln⎜ REF S 2 ⎟ = ln⎜ ⎟ = 9.78 kΩ I o2 ⎝ IO2 I S1 ⎠ 10µA ⎝ 10µA 1 ⎠ ⎛I ⎛ 50µA n ⎞ I ⎞ I o3 R3 = VT ln⎜ REF S 3 ⎟ | (10µA)(2kΩ)= 0.025V ln⎜ ⎟ → n = 0.445 ⎝ 10µA 1 ⎠ ⎝ IO3 I S1 ⎠ [ ] 15.165 For the current mirror at the bottom: IC 2 = β F IB 2 | IE 3 = IC1 + IB1 + IB 2 = nβ F IB 2 + nIB 2 + IB 2 IC 2 = βF β F 1+ n (β F + 1) I IE 3 | IO = α F IE 3 = IC 2 | IC 2 = IREF − IB 3 = IREF − O 1+ n (β F + 1) βF + 1 βF βF n+ IO = 1 1+ n(β F + 1) ⎛ β F (β F + 1) I ⎞ n IREF ≅ I ≅ nIREF for β F >> n ⎜ IREF − O ⎟ → IO = n REF n 1 βF + 1 ⎝ βF ⎠ 1+ 1+ + β F β F (β F + 1) βF (a) IO ≅ 1 50µA = 49.6 µA | Rout ≅ β o ro = 125 40 − 0.7 − (−5) V = 55.8 MΩ 49.6 µA 2 1 2 125 β r 125 44.3 V 3 50µA = 146 µA | Rout ≅ o o = = 19.0 MΩ (b) IO ≅ 3 146 2 µ A 2 1+ 125 (c ) VCS = IO Rout = 146µA(19.0MΩ) = 2770V (d) VCB 3 = VEE − 0.7V − 0.7V ≥ 0 → VEE ≥ 1.40V 15-100 1+ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.166 i1 + βo i 1 r π3 v1 r o3 vb ix 1 gm1 i i vx ix ve r o2 + - - ⎡ix ⎤ ⎡gm1 + gπ 3 −gπ 3 ⎤⎡v e ⎤ | ⎢ ⎥=⎢ ⎥⎢ ⎥ ⎣0 ⎦ ⎣gm1 − gπ 3 gπ 3 + go2 ⎦⎣v b ⎦ IC1 ≅ IC 2 ≅ IC 3 so the small - signal parameters are matched ⎛ β 1⎞ ∆ = 2gm1gπ 3 + gm1go2 + gπ 3 go2 = gm1gπ 3 ⎜⎜2 + o + ⎟⎟ ≅ 2gm1gπ 3 for µ f >> β o >> 1 µf µf ⎠ ⎝ g + go2 g −g i ⎛ β ⎞ i = x ⎜⎜1+ o ⎟⎟ ≅ x | v b = −ix m1 π 3 v e = ix π 3 ∆ 2gm1 ⎝ µ f ⎠ 2gm1 ∆ g + go2 i ⎛ 1⎞ i i v b − v e = −ix m1 = − x ⎜⎜1+ ⎟⎟ ≅ x rπ 3 | i1 = gπ 3 (v b − v e ) = x ∆ 2gπ 3 ⎝ µ f ⎠ 2 2 i βr βr i v 1 v x = v e + (ix − β oi1)ro3 = x + ix ro3 + β o ro3 x | Rout = x = + ro3 + o o3 ≅ o o3 2gm1 2 ix 2gm1 2 2 Rout = vx ix 15.l67 Rout ≅ β oro 2 ≅ β oVA 2IO = β oVA 2nI REF | For Prob. 15.165, Rout ≅ 125(40) 2n (50µA) = 50 MΩ n 15.168 VCB3 = VC 3 − VBE3 − VBE 2 − (−VEE )≥ 0 → VC 3 ≥ −VEE + VBE 3 + VBE2 IC 3 I I I I β +1 + VT ln C1 | IC1 + C1 + C1 = C 3 ≅ F I | From Prob. IS3 I S1 β F nβ F α F βF C3 VBE3 + VBE1 = VT ln 15.165 : IC3 ≅ n 1+ n βF 5 I REF = 1+ 5 125 15µA = 72.1µA | IC1 = βF + 1 I = 72.0µA 1 1 β F C3 + 1+ β F nβ F 1 ⎛ 72.1µA 72.0µA ⎞ + ln VBE3 + VBE 2 = 0.025V ⎜ ln ⎟ = 1.16V | VC 3 ≥ −VEE + 1.16 V 3 fA 15 fA ⎠ ⎝ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-101 15.169 (a) Assuming balanced drain voltages, I VGS1 = VTN + 2I D1 2I REF = 0.75 + Kn1 4 5Kn' 5 − 0.75 − I REF = ( ) 2I REF ( ) 4 5K ' n D3 = I D1 = I REF | VGS 3 = 0.75 + 2I REF − 0.75 − ( 4 20Kn' 30kΩ ) | ⎛W ⎞ ⎜ ⎟ ⎝ L ⎠1 I REF = ⎛W ⎞ 4 ⎜ ⎟ ⎝ L ⎠2 2I REF ( 4 20Kn' (30kΩ)I REF | I REF = 5 − VGS1 − VGS 3 30kΩ ) = 3.5 −1.5 I REF 10Kn' 2 Using Kn' = 25x10-6 and rearranging : 9x108 I REF − 2.19x105 I REF + 12.25 = 0 I REF = 21.8 µA. Drain voltage balance on M1 and M2 4 ⎛ W ⎞ 80 2I REF 2I REF | VTN + = VTN + | ⎜ ⎟ = ⎛W ⎞ ' ⎝ L ⎠4 1 4 20Kn' ⎜ ⎟ Kn ⎝ L ⎠4 I REF = 87.2 µA and IO = requires VGS 4 = VGS 3 ( ) (b) This part requires an iterative solution or the use of a computer solver. Assuming VDS balance between M1 and M2 , λ ≠ 0 will not affect the current mirror ratio, but it will change VGS and hence I REF slightly. One iterative approach : Guess VGS1 | Then I D1 = 2 5Kn' VGS1 − VTN ) (1+ λVGS1 ) ( 2 Since I D3 = I D1 , VGS 3 = VTN + [ 2I DS1 ] 20K 1+ λ (5 − VGS1 ) ' n 5 − VGS1 − VGS 3 I and I D1 = REF . 30kΩ 4 If the second value of I D1 does not agree with the first, then try a new VGS1. I REF = A spreadsheet yields : VGS1 = 1.336V , VGS 3 = 1.381V , I REF = 87.5µA, IO = 21.7µA. Note: There is essentially no change from the first answer! 15-102 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.169 cont. (c) *Problem 15.169 - NMOS Wilson Source RREF 1 0 30K VSS 4 0 DC -5 M1 3 3 4 4 NFET W=5U L=1U M2 2 3 4 4 NFET W=20U L=1U M3 0 1 3 3 NFET W=20U L=1U M4 1 1 2 2 NFET W=80U L=1U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.015 .OP .END 15.170 IO = I REF Rout = 1 λ2 ⎛W ⎞ ⎜ ⎟ ⎝ L ⎠1 ⎛W ⎞ ⎜ ⎟ ⎝ L ⎠2 | Rout = µ f 2ro3 = µ f 2 ⎛W ⎞ 2⎜ ⎟ Kn' 1 ⎝ L ⎠2 I REF λ3 I REF 1 1 = λ3 IO λ2 2Kn 1 I D2 λ3 IO 3 ⎡⎛ W ⎞ ⎤2 ⎛W ⎞ ⎢⎜ ⎟ ⎥ ⎜ ⎟ 1 ⎢⎝ L ⎠2 ⎥ ⎝ L ⎠2 = ⎛ W ⎞ λ2 λ3 ⎢ I REF ⎥ ⎜ ⎟ ⎥ ⎢ ⎝ L ⎠1 ⎦ ⎣ 2Kn' ⎛W ⎞ ⎜ ⎟ ⎝ L ⎠1 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-103 15.171 ix M3 + - vx + ro2 v - gm2 v ix = go2v x + gm 2v1 ix = go2v x + gm 2 vx 2 1 g m1 ⎛ 1 ⎞ gm 3 ⎜ ⎟ v ⎝ gm1 ⎠ | v1 = v x = x ⎛ 1 ⎞ 2 1+ gm 3 ⎜ ⎟ ⎝ gm1 ⎠ | Rin = | gm1 = gm 3 | v1 = vx 2 2 vx 2 = ro ≅ ix gm 2 gm 2 15.172 ⎛W ⎞ ⎜ ⎟ ⎝ L ⎠1 150µA Since λ = 0, ID 3 = ID1 = IREF = = 37.5µA ⎛W ⎞ 4 ⎜ ⎟ ⎝ L ⎠2 VDS 3 ≥ VGS 3 − VTN 3 | VD 3 − (−10 + VGS1 ) ≥ VGS 3 − VTN 3 | VD 3 ≥ −10 + VGS1 + VGS 3 − VTN 3 VD 3 ≥ −10 + VTN1 + 2ID1 2ID 3 + VTN 3 + − VTN 3 K n1 Kn 3 2(37.5µA)V 2 2(37.5µA)V 2 VD 3 ≥ −10V + 0.75V + + = −8.09 V 5(25µA) 20(25µA) 15.173 ⎛W ⎞ ⎛W ⎞ 1 1 Rout ≅ µ f 2 ro3 | ⎜ ⎟ = ⎜ ⎟ ⇒ IO = IREF = 50µA | ro3 ≅ = = 1.60MΩ ⎝ L ⎠ 2 ⎝ L ⎠1 λID 3 0.0125(50µA) µf 2 = Rout 250MΩ 1 2K n = = 156 | Using Eq. 13.71, µ f 2 = ro3 1.60MΩ λ ID 2 ⎛W ⎞ 2 I 2 5x10−5 3.80 = ⎜ ⎟ = (λµ f 2 ) D 2' = [0.0125(156)] −5 ⎝ L ⎠2 2K n 1 2(2.5x10 ) 15.174 15-104 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 The circuit is the same as Fig. 16.20 with the addition of RREF in parallel with ro2. We require RREF >> ro2 in order not to reduce the gain of the feedback loop. A current source with a source resistor which achieves ROUT = ro(1+gmRs) should be sufficient. A cascode or Wilson source will also work. 15.175 M1 and M2 are voltage balanced. (a) Rout = µ f 4ro2 | All Kn are the same : IO = I REF = 17.5µA VGS1 = 0.75 + ( 2 17.5x10−6 −6 75x10 ) = 1.43V | ∆V3 = VGS 3 − VTN 3 = 1.43V − 0.75V = 0.680 1 1 + 1.43 + (5 −1.43) = 4.65MΩ | ro4 = 0.0125 = 4.78 MΩ ro2 = 0.0125 17.5µA 17.5µA ( )( )( ) g m4 = 2 75x10−6 17.5x10−6 1+ 0.0125(5 −1.43) = 5.24x10−5 S µ f 4 = 5.24x10−5 S (4.78 MΩ) = 250 | Rout = 1.16 GΩ min (b) VCS = IO Rout = 20.3 kV! (c) VDD = VGS1 + ∆V4 = 1.43 + 0.680 = 2.11V 15.176 *Problem 15.176 - NMOS Cascode Source IREF 0 1 DC 17.5U VDD 2 0 DC 5 M1 3 3 0 0 NFET W=3U L=1U M2 4 3 0 0 NFET W=3U L=1U M3 1 1 3 3 NFET W=3U L=1U M4 2 1 4 4 NFET W=3U L=1U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.0125 .OP .TF I(VDD) VDD .END Results: IO = 17.5 µA ROUT = 1.17 GΩThe same as the hand analysis. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-105 15.177 ⎛W ⎞ ⎜ ⎟ ⎝L⎠ (a) M1 and M 2 are voltage balanced, so IO = ⎛ W ⎞2 IREF = 1.05IREF = 18.4µA, a 5% error. ⎜ ⎟ ⎝ L ⎠1 (b) To first order, IO does not depend upon W/L of M 3 and M 4 . The mismatch will create a small VDS mismatch between M1 and M 2 , but this error will be negligible. An estimate of this effect is ∆Io = go2∆VDS where ⎛ 2ID 2ID 3 ⎞ ⎛ 2ID 4 ⎞ 2ID 2ID ∆VDS = VGS 3 − VGS 4 = ⎜VTN + − = 0.026 ⎟ − ⎜VTN + ⎟= Kn 3 ⎠ ⎝ Kn 4 ⎠ Kn3 0.95K n 3 Kn3 ⎝ ∆VDS = 0.026 2(17.5) = 0.0218V | ∆Io = 0.0125(17.5x10−6 )(0.0218) = 3.89 nA 50 15.178 ⎛W ⎞ ⎛W ⎞ 1 1 Rout = µ f 4 ro2 | ⎜ ⎟ = ⎜ ⎟ ⇒ IO = IREF = 50µA | ro2 ≅ = = 1.60MΩ ⎝ L ⎠ 2 ⎝ L ⎠1 λID 2 0.0125(50µA) µf 4 = Rout 250MΩ 1 2K n 4 = = 156 | Using Eq. 13.71, µ f 4 = ro2 1.60MΩ λ ID 4 ⎛W ⎞ 2 I 2 5x10−5 3.80 = ⎜ ⎟ = (λµ f 4 ) DS 4' = [0.0125(156)] −5 ⎝ L ⎠4 2K n 1 2(2.5x10 ) 15-106 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.179 (a − a) Rout = µ f 4 ro2 | All K n are the same : IO = IREF = 25µA VGS1 = 0.75 + 2(25x10−6 ) 75x10−6 = 1.57V | ∆V3 = VGS 3 − VTN 3 = 1.57V − 0.75V = 0.817V 1 1 + 1.57 + (5 −1.57) = 3.26MΩ | ro4 = 0.0125 = 3.38MΩ ro2 = 0.0125 25µA 25µA gm 4 = 2(75x10−6 )(25x10−6 )(1+ 0.0125(5 −1.57)) = 6.25x10−5 S µ f 4 = 6.25x10−5 S (3.38MΩ) = 211 | Rout = 689 MΩ min (a − b) VCS = IO Rout = 17.2 kV! (a - c) VDD = VGS1 + ∆V4 = 1.57 + 0.817 = 2.39 V (b − a) Rout = µ f 4 ro2 | All K n are the same : IO = IREF = 25µA VGS1 = 0.75 + 2(50x10−6 ) 75x10−6 = 1.91V | ∆V3 = VGS 3 − VTN 3 = 1.91V − 0.75V = 1.16V 1 1 + 1.91 + (5 −1.91) = 1.64 MΩ | ro4 = 0.0125 = 1.66MΩ ro2 = 0.0125 50µA 50µA gm 4 = 2(75x10−6 )(50x10−6 )(1+ 0.0125(5 −1.91)) = 8.83x10−5 S µ f 4 = 8.83x10−5 S (1.66MΩ) = 147 | Rout = 240 MΩ min (b − b) VCS = IO Rout = 12.0 kV! (b - c) VDD = VGS1 + ∆V4 = 1.91+ 1.16 = 3.07 V 15.180 1 1 2 2 R= + = = = 39.0 kΩ −6 gm 3 gm1 gm1 2(75x10 )(17.5x10−6 ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-107 15.181 (a ) I = IC 3 + I B3 + I B 4 = I E3 + I B 4 = IC1 + REF I REF IC1 = 1+ 2 βF + 1 βF + 1 2IC1 βF + IC 2 2I I = IC1 + C1 + C1 βF + 1 βF βF + 1 | IO = IC 4 = α F IC 2 = α F IC1 = βF βF + 1 I REF 1+ 2 βF + 1 βF + 1 ⎛ ⎞ ⎜ 110(50) 17.5µA ⎟ βr 110 IO = = 163 MΩ ⎜ ⎟ = 16.9 µA | Rout = o o ≅ 2 1 ⎟ 2 111 ⎜ 2(16.9µA) 1+ + ⎝ 110 111 ⎠ (b) V CS = IO Rout = 16.9µA(163MΩ) = 2750 V (c) V CC ≥ 2VBE = 1.40 V 15.182 *Figure 15.182 - NPN Cascode Current Source IREF 0 1 17.5U VCC 2 0 DC 5 Q1 3 3 0 NBJT 1 Q2 4 3 0 NBJT 1 Q3 1 1 3 NBJT 1 Q4 2 1 4 NBJT 1 .MODEL NBJT NPN BF=110 VA=50 .OP .TF I(VCC) VCC .END Results: IO = 16.9 µA Rout = 164 MΩ  the same as the hand analysis 15.183 ⎛ 1 ⎞ 1 + rπ 2 ⎟ R =⎜ ⎝ g m3 g m1 ⎠ 15-108 [r + (β π4 o4 ] + 1)ro2 ≅ 1 1 2 2 + ≅ = = 2.86 kΩ g m3 g m1 g m1 40(17.5µA) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.184 (a) Assuming β IO = o = 80 and VA = 60V : VT ⎛ I REF AE2 ⎞ 0.025V ⎛ 80µA ⎞ 20⎟ → IO = 127 µA ⎟= ⎜ ln ⎜ ln R2 ⎝ IO AE1 ⎠ 500Ω ⎝ IO ⎠ 100(0.025) 60V + 10 − 0.0635 = 551kΩ | rπ 2 = = 19.7kΩ | g m1 = 40(80µA) = 3.2mS 0.127mA 0.127mA ⎞ ⎛ ⎟ ⎜ ⎞ ⎛ 100(0.5kΩ) β o R2 ⎟ = 551kΩ⎜1+ ⎟ Rout = ro2 ⎜1+ ⎜ 0.313kΩ + 19.7kΩ + 0.5kΩ ⎟ = 1.89 MΩ 1 ⎟ ⎜ ⎠ ⎝ + rπ 2 + R2 ⎟ ⎜ g ⎠ ⎝ m1 ⎛ ⎞ 0.025V 80µA (b) IO = 500Ω ⎜⎝ ln I 20(1.05)⎟⎠ → IO = 129 µA O ⎛ A ⎞ 0.025V ⎛ 80µA ⎞ V I (c) IO = RT ⎜⎝ ln IREF AE 2 ⎟⎠ = 500Ω ⎜⎝ ln I 14⎟⎠ → IO = 114 µA 2 O E1 O ro2 = ro2 = Rout 100(0.025) 60V + 10 − 0.057 = 614kΩ | rπ 2 = = 21.9kΩ | g m1 = 40(80µA)= 3.2mS 0.114mA 0.114mA ⎛ ⎞ 100(0.5kΩ) ⎟ = 1.97 MΩ = 614kΩ⎜⎜1+ ⎟ 0.313kΩ + 21.9kΩ + 0.5kΩ ⎝ ⎠ 15.185 Assuming βo = 80 and VA = 60V : V ⎛ I A ⎞ 0.025V ⎛ 35µA ⎞ (a) IO = RT ⎜⎝ ln IREF AE 2 ⎟⎠ = 935Ω ⎜⎝ ln I 20⎟⎠ → IO = 64 µA 2 O E1 O 100(0.025) 60V + 10 − 0.0598 = 1.09 MΩ | rπ 2 = = 39.1kΩ | g m1 = 40(35µA) = 1.40mS 0.064mA 0.064mA ⎞ ⎛ ⎟ ⎜ ⎞ ⎛ 100(0.935kΩ) β o R2 ⎟ ⎜ ⎟ = 3.59 MΩ ⎜ = 1.09 MΩ⎜1+ Rout = ro2 1+ ⎟ 1 0.714kΩ + 39.1kΩ + 0.935kΩ ⎟ ⎜ ⎠ ⎝ + rπ 2 + R2 ⎟ ⎜ ⎠ ⎝ g m1 V ⎛ I A ⎞ 0.025V ⎛ 35µA ⎞ (b) IO = RT ⎜⎝ ln IREF AE 2 ⎟⎠ = 935Ω ⎜⎝ ln I 10⎟⎠ → IO = 51.3 µA 2 O E1 O ro2 = ro2 = Rout 100(0.025) 60V + 10 − 0.0480 = 1.36 MΩ | rπ 2 = = 48.7kΩ | g m1 = 40(35µA)= 1.40mS 51.3µA 51.3µA ⎞ ⎛ ⎟ ⎜ ⎞ ⎛ 100(0.935kΩ) β o R2 ⎟ = 1.36 MΩ⎜1+ ⎜ ⎟ = ro2 1+ ⎜ 0.714kΩ + 48.7kΩ + 0.935kΩ ⎟ = 3.89 MΩ 1 ⎟ ⎜ ⎠ ⎝ + rπ 2 + R2 ⎟ ⎜ ⎠ ⎝ g m1 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-109 15.186 VT ⎛ IREF ⎜ ln IO ⎝ IO V ⎛ I (b) R2 = T ⎜ln REF IO ⎝ IO (a) R2 = (c ) R2 = VT IO AE 2 ⎞ 0.025V ⎛ 73µA ⎞ 20⎟ = 4.77 kΩ ⎟= ⎜ln AE1 ⎠ 22µA ⎝ 22µA ⎠ AE 2 ⎞ 0.025V ⎛ 73µA ⎞ 20⎟ = 24.3 kΩ ⎟= ⎜ln AE1 ⎠ 5.7µA ⎝ 5.7µA ⎠ ⎛ IREF AE 2 ⎞ 0.025V ⎛ 73µA ⎞ 10⎟ = 21.3 kΩ ⎟= ⎜ ln ⎜ln ⎝ IO AE1 ⎠ 5.7µA ⎝ 5.7µA ⎠ 15.187 VT ⎛ IREF ⎜ ln IO ⎝ IO V ⎛ I (b) R2 = T ⎜ln REF IO ⎝ IO (a) R2 = AE 2 ⎞ 0.025V ⎛ 62µA ⎞ 10⎟ = 8.22 kΩ ⎟= ⎜ln AE1 ⎠ 12µA ⎝ 12µA ⎠ AE 2 ⎞ 0.025V ⎛ 62µA ⎞ 10⎟ = 8.22 kΩ ⎟= ⎜ln AE1 ⎠ 512µA ⎝ 512µA ⎠ 15.188 *Problem 15.188 - NPN Widlar Current Source IREF 2 1 50U VCC 2 0 DC 10 Q1 1 1 0 NBJT 1 Q2 2 1 3 NBJT 20 R2 3 0 4K .MODEL NBJT NPN BF=110 .OP .DC IREF 50U 5M 50U .PROBE IC(Q2) .END 50uA I O2 40uA 30uA I REF 20uA 0A 15-110 1.0mA 2.0mA 3.0mA 4.0mA 5.0mA ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.189 ⎛V ⎞ V V I IO = α F IE 2 = α F ⎜ BE1 + IB1 ⎟ ≅ BE1 = T ln C1 R2 IS1 ⎝ R2 ⎠ R2 V − VBE 2 − VBE1 V − VBE 2 − VBE1 IC1 = EE − IB 2 ≅ EE R1 R1 0.025V 15 −1.4 V 0.7V ln 4 −15 = 318 µA | Note : BE1 ≅ = 318 µA (a) IC 2 ≅ R2 2.2kΩ 10 (10 ) 2.2kΩ (b) IC 2 ≅ 0.025V 3.3 −1.4 V 0.7V ln 4 −15 = 295 µA | Note : BE1 ≅ = 318 µA R2 2.2kΩ 10 (10 ) 2.2kΩ (c ) IC 2 ≅ VT VCC − VEB1 − VEB 2 0.025V 5 −1.4 0.7V ln = ln 4 −15 = 66.5 µA | = 70 µA R2 IS1R1 10kΩ 10 (10 ) 10kΩ 15.190 VEE − VBE 2 − VBE1 3.3 −1.4 − IB 2 ≅ = 317kΩ 6µA IC1 ⎛ 6µA ⎞ I VT ln C1 0.0258V ⎜ln ⎟ ⎛V ⎞ IS1 ⎝ 0.1 fA ⎠ = = 21.2kΩ IO = α F IE 2 = α F ⎜ BE1 + IB1 ⎟ | R2 = 131 IO 6µA ⎝ R2 ⎠ −I (30µA) − 130 α F B1 130 (a) Choose IC1 = 0.2IO | R1 = (b) This is the same circuit implemented with pnp transistors. VCC − VEB 2 − VEB1 3.3 −1.4 − IB 2 ≅ = 317kΩ 6µA IC1 ⎛ 6µA ⎞ I VT ln C1 0.0258V ⎜ln ⎟ ⎛V ⎞ IS1 ⎝ 0.1 fA ⎠ EB1 + IB1 ⎟ | R2 = = = 21.2kΩ IO = α F IE 2 = α F ⎜ IO 6µA 131 ⎝ R2 ⎠ −I (30µA) − 130 α F B1 130 Choose IC1 = 0.2IO | R1 = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-111 15.191 i + −β o i r π4 v1 r o4 R th + - ix i vx ix - + r o2 ve - v x = v1 + v e = (ix − β oi1)ro4 + (ix − 2i)ro2 | i1 = −i | v x = (ix + β oi)ro4 + (ix − 2i)ro2 i= (ix − 2i)ro2 rπ 4 + Rth i = ix where Rth = µf 2 β o4 + 2µ f 2 ≅ 1 1 (i − 2i)ro2 + << rπ 4 | i ≅ x rπ 4 gm 3 gm 2 | i = ix ro2 rπ 4 + 2ro2 ⎞ ⎛ βr ix for 2µ f 2 >> β o | v x = ix ⎜ ro2 + ro4 + o o4 − ro2 ⎟ ⎠ ⎝ 2 2 ⎛β ⎞ βr Rout ≅ ro4 ⎜ o + 1⎟ ≅ o o4 ⎝2 ⎠ 2 for Rth << rπ 4 and 2µf2 >> β o 15.192 An iterative solution is required : 1. Choose VGS 2 . Then I D2 = [ ] 2 Kn2 VGS 2 − VTN 2 ) 1 + λ (VDD − I D2 R1 ) ( 2 2 Kn2 VGS 2 − VTN 2 ) (1 + λVDD ) ( or I D2 = 2 and 2 Kn2 1+ (VGS 2 − VTN 2 ) (λR1) 2 2I D1 2. VGS1 = VTN1 + Kn1 1 + λ(VDD − I D1 R2 ) [ 3. I D2 = I D1 = VGS 2 R2 ] VDD − VGS1 − VGS 2 Compare to I D2 in step 1 and choose new VGS 2 R1 −−−−− I D2 2 2.5x10-4 VGS 2 − 0.75) (1.17) ( V 2 = | I D1 = GS 2 -4 2 15kΩ 2.5x10 1+ VGS 2 − 0.75) (0.017 *10000) ( 2 VGS1 = 0.75 + [ 2I D1 ] 2.5x10 1 + 0.017(10 −15000I D1) -4 | I D2 = 10 − VGS1 − VGS 2 10kΩ Iteration yields VGS 2 = 2.744V , IO = I D2 = 536 µA, and I D1 = 183 µA. 15-112 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.193 Choose ID 2 = 0.2IO = 15µA | The effect of λ1 can be ignored because of the presence of 2(75x10−6 ) 2ID1 = 0.75 + = 1.53V | Then, resistor R2 : VGS1 = VTN1 + K n1 250x10−6 Kn 2 250µA 2 2 (VGS 2 − VTN 2 ) [1 + λ(VGS 2 + VGS1 )] | 15µA = (VGS 2 − 0.75) [1 + λ(VGS 2 + 1.53)] 2 2 V 1.09V An iterative solution gives VGS 2 = 1.089V | R2 = GS 2 = = 14.5 kΩ IO 75µA V − VGS1 − VGS 2 6 −1.53 −1.09 R1 = DD = = 225 kΩ ID 2 15µA ID 2 = 15.194 An iterative solution is required : 1. Choose VGS1. Then I D1 = K p1 2 (V GS1 [ 2 K p1 2 VGS1 − VTP1 ) (1 + λVDD ) ( or I D2 = 2 and K p1 2 1+ (VGS1 − VTP1) (λR1) 2 2I D2 2. VGS 2 = VTP2 − KP2 1 + λ(VDD − I D2 R2 ) [ 3. I D1 = ] − VTP1) 1 + λ (VDD − I D1 R1 ) I D2 = VSG1 R2 ] VDD − VSG1 − VSG2 Compare to I D2 in step 1 and choose new VGS1 R1 −−−−− 2 10-4 VGS1 + 0.75) (1.10) ( 2 I D1 = -4 | I D2 = 2 10 VGS1 + 0.75) (0.02 *10000) ( 2 2I D2 VGS 2 = −0.75 − -4 10 1 + 0.02(5 −18000I D2 ) 1+ [ ] VGS1 18kΩ | I D1 = 5 − VSG1 − VSG2 10kΩ Iteration yields VGS1 = −1.984V , IO = I D2 = 110 µA, and I D1 = 82.4 µA. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-113 15.195 Choose ID1 = 0.2IO = 25µA | The effect of λ2 can be ignored because of the presence of resistor R2 : VGS 2 = VTP 2 − 2(125x10−6 ) 2ID 2 = −0.75 − = −2.33V | Then, KP 2 100x10−6 K p1 100µA 2 2 (VGS1 − VTP1 ) 1 + λ(VGS1 + VGS 2 ) | 25µA = (VGS1 + 0.75) 1 + λ(VGS1 + 2.33) 2 2 VGS 1.43V An iterative solution gives VGS1 = −1.432V | R2 = − = = 11.4 kΩ IO 125µA V + VGS1 + VGS 2 9 −1.43 − 2.33 = = 210 kΩ R1 = DD 25µA ID1 [ ID1 = ] 15.196 IC1 = IC 3 = 3IC 4 | IC 4 = IC 2 = IC 2 = [ VBE1 − VBE 2 VT ⎛ IC1 I ⎞ V ⎛ I I ⎞ = ⎜ln − ln C 2 ⎟ = T ⎜ln C1 S 2 ⎟ R R ⎝ IS1 IS 2 ⎠ R ⎝ IC 2 IS1 ⎠ 0.025V ⎛ 3IC 2 20A ⎞ ⎜ln ⎟ = 46.5 µA | IC1 = 3IC 2 = 140 µA 2.2kΩ ⎝ IC 2 A ⎠ 15.197 *Problem 15.197 - BJT reference current cell P15.196 VCC 1 0 DC 1.5 AC 1 VEE 5 0 DC -1.5 Q4 2 2 1 PBJT 1 Q3 3 2 1 PBJT 3 Q1 3 3 5 NBJT 1 Q2 2 3 4 NBJT 20 R 4 5 2.2K .MODEL NBJT NPN BF=100 VA=50 .MODEL PBJT PNP BF=100 VA=50 .OP .AC LIN 1 1000 1000 .PRINT AC IC(Q1) IC(Q2) .END Results: IC1 = 140 µA IC2 = 47.8 µA 15.198 IC1 = IC 3 = 3IC 4 | IC 4 = IC 2 = IC 4 = IC 2 = VBE1 − VBE 2 VT = R R S IVC1CC = 2. 92 x10 −2 ⎛ IC1 I ⎞ V − ln C 2 ⎟ = T ⎜ln IS 2 ⎠ R ⎝ IS1 S IVC2CC = 9 . 92 x 10 −3 ⎛ IC1 IS 2 ⎞ ⎜ln ⎟ ⎝ IC 2 IS1 ⎠ 0.025V ⎛ 3IC 2 8A ⎞ ⎜ ln ⎟ = 19.9 µA | IC1 = 3IC 2 = 59.6 µA | IC 3 = IC1 = 59.6 µA 4kΩ ⎝ IC 2 A ⎠ 15.199 15-114 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ] VBE1 − VBE 2 must be greater than 0. | VBE1 − VBE 2 = VT ( ) > 0 ln nA 1 IC1IS 2 > 0 or 3 >1 | n > IC 2 IS1 A 3 15.200 VBE1 − VBE 2 VT ⎛ IC1 I ⎞ V ⎛I I ⎞ = ⎜ ln − ln C 2 ⎟ = T ln⎜ C1 S 2 ⎟ R R ⎝ IS1 IS 2 ⎠ R ⎝ IC 2 IS1 ⎠ −23 kT 1.38x10 (323) V ⎛ I I ⎞ 27.9mV = = 0.0279V | R = T ln⎜ C1 S 2 ⎟ = ln(3⋅ 5) = 2.16 kΩ VT = −19 q 1.6x10 IC 2 ⎝ IC 2 IS1 ⎠ 35µA −23 kT 1.38x10 (273) VT ⎛ IC1 IS 2 ⎞ 23.6mV = 0.0236V | R = ln⎜ ln(3⋅10) = 2.29 kΩ (b) VT = = ⎟= q 1.6x10−19 IC 2 ⎝ IC 2 IS1 ⎠ 35µA (a) IC1 = IC 3 = 3IC 4 | IC 4 = IC 2 = 15.201 The M 3 - M 4 current mirror forces ID1 = ID 2 . VGS1 − VGS 2 = ID 2 R | ID 2 R = VTN + ID 2 = 2ID1 2ID 2 − VTN − ' 10K n 20K n' | ID 2 R = 2ID 2 ⎛ 1 ⎞ 1− ⎟ ' ⎜ 10K n ⎝ 2⎠ 0.293 1 0.293 1 = ⇒ ID 2 = 26.4 µA ' R 5K n 5100 5(25x10−6 ) 15.202 (a) The M 3 - M 4 current mirror forces ID1 = ID 2 . VGS1 − VGS 2 = ID 2 R | ID 2 R = VTN1 + ID 2 = 1 0.293 1 0.293 = ⇒ ID 2 = 6.86 µA 4 ' 5K n R 10 5(25x10−6 ) (b) VTN1 = VTO ID 2 R = VTO + ID 2 = 2ID1 2ID 2 2ID 2 ⎛ 1 ⎞ − VTN 2 − | ID 2 R = 1− ⎟ ' ' ' ⎜ 10K n 20K n 10K n ⎝ 2⎠ | VTN 2 = VTO + γ ( 2φ F ) ( + VSB − 2φ F = VTO + 0.5 0.6 + ID 2 R − 0.6 ( ) ) 2ID1 2ID 2 − VTO − 0.5 0.6 + ID 2 R − 0.6 − ' 10K n 20K n' 0.293 2IDS 2 0.5 − 10 4 10K n' 10 4 ( 0.6 + 10 I 4 D2 ) − 0.6 → ID 2 = 3.96 µA ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-115 15.203 This problem should refer to Prob. 15.202 (a) and (b) *Problem 15.203(a) - MOS reference current cell VDD 1 0 DC 5 AC 1 VSS 5 0 DC -5 M1 3 3 5 5 NFET W=10U L=1U M2 2 3 4 5 NFET W=20U L=1U M3 3 2 1 1 PFET W=10U L=1U M4 2 2 1 1 PFET W=10U L=1U R 4 5 10K .MODEL NFET NMOS KP=25U VTO=0.75 PHI=0.6 GAMMA=0 LAMBDA=0.017 .MODEL PFET PMOS KP=10U VTO=-0.75 PHI=0.6 GAMMA=0 LAMBDA=0.017 *.MODEL NFET NMOS KP=25U VTO=0.75 PHI=0.6 GAMMA=0 LAMBDA=0 *.MODEL PFET PMOS KP=10U VTO=-0.75 PHI=0.6 GAMMA=0 LAMBDA=0 *Problem 15.203(b) - MOS reference current cell *.MODEL NFET NMOS KP=25U VTO=0.75 PHI=0.6 GAMMA=0.5 LAMBDA=0.017 *.MODEL PFET PMOS KP=10U VTO=-0.75 PHI=0.6 GAMMA=0.75 LAMBDA=0.017 .OP .AC LIN 1 1000 1000 .PRINT AC ID(M1) ID(M2) .END Results: (a) ID2 = 13.9 µA ID2 = 12.3 µA D1 D2 SVI DD = 7.64 x10−2 SVI DD = 6.23x10−2 The currents differ considerably from the hand calculations. D1 D2 = 7.75x10−2 SVI DD = 6.31x10−2 Results: (b) ID1 = 8.19 µA ID2 = 7.24 µA SVI DD The currents differ considerably from the hand calculations. The currents are quite sensitive to the value of λ. The hand calculations used λ = 0. If the simulations are run with λ = 0, then the results are identical to the hand calculations. 15.204 V ⎛ I 5A ⎞ 0.025V ⎛ 2IC 2 5A ⎞ IC 2 = T ln⎜ C1 ln⎜ ⎟ | IC1 = IC 3 = 2IC 4 = 2IC 2 | IC 2 = ⎟ = 5.23 µA R ⎝ A IC 2 ⎠ 11kΩ ⎝ A IC 2 ⎠ V ⎛ I 3A ⎞ 0.025V ⎛15.7µA ⎞ IC 7 = 5IC 4 = 5(5.23µA) = 26.2 µA | IC 8 = T ln⎜ C 4 ln⎜ ⎟= ⎟ → IC 8 = 6.00 µA R8 ⎝ A IC 8 ⎠ 4kΩ ⎝ IC 8 ⎠ V ⎛ I A ⎞ 0.025V ⎛ 10.4µA ⎞ ln⎜ IC 5 = 2.5IC1 = 5IC 2 = 26.2 µA | IC 6 = T ln⎜ C1 ⎟= ⎟ → IC 6 = 5.42 µA R6 ⎝ A IC 6 ⎠ 3kΩ ⎝ IC 6 ⎠ 15-116 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.205 V ⎛ I 10A ⎞ 0.025V ⎛ IC 2 10A ⎞ IC 2 = T ln⎜ C1 ln⎜ ⎟ | IC1 = IC 3 = IC 4 = IC 2 | IC 2 = ⎟ = 5.23 µA R ⎝ A IC 2 ⎠ 11kΩ ⎝ A IC 2 ⎠ V ⎛ I 3A ⎞ 0.025V ⎛15.7µA ⎞ IC 7 = 5IC 4 = 5(5.23µA) = 26.2 µA | IC 8 = T ln⎜ C 4 ln⎜ ⎟= ⎟ → IC 8 = 6.00 µA R8 ⎝ A IC 8 ⎠ 4kΩ ⎝ IC 8 ⎠ V ⎛ I A ⎞ 0.025V ⎛ 5.23µA ⎞ ln⎜ IC 5 = 2.5IC1 = 13.1 µA | IC 6 = T ln⎜ C1 ⎟= ⎟ → IC 6 = 3.45 µA R6 ⎝ A IC 6 ⎠ 3kΩ ⎝ IC 6 ⎠ 15.206 VT ⎛ IC1 IS 2 ⎞ 0.025V ⎛ 2IC 2 7IS1 ⎞ ⎜ln ⎟= ⎜ln ⎟ = 15.3 µA R ⎝ IC 2 IS1 ⎠ 4.3kΩ ⎝ IC 2 IS1 ⎠ = IC 5 = IC 6 = IC1 = 30.6 µA | IC 3 = IC 7 = IC 2 = 15.3 µA (a) IC1 = 2IC 2 set by Q 4 and Q 3 IC1 = 2IC 2 = 30.6 µA | IC 4 (b) No change. | IC 2 = The currents are independent of the areas of Q5 , Q6 , and Q7 . 15.207 *Problem 15.207 - NPN Cascode Current Source VCC 1 0 DC 5 AC 1 Q4 2 2 1 PBJT 2 Q3 3 2 1 PBJT 1 Q5 4 3 2 PBJT 1 Q1 6 6 0 NBJT 1 Q2 5 6 7 NBJT 7 Q6 4 4 6 NBJT 1 Q7 3 4 5 NBJT 1 R 7 0 4.3K .MODEL NBJT NPN BF=100 VA=50 .MODEL PBJT PNP BF=50 VA=50 .OP .AC LIN 1 1000 1000 .PRINT AC IC(Q7) IC(Q5) .END Results: IC2 = 15.2 µA IC1 = 28.5 µA - Similar to hand calculations. C1 C2 = 1.81x10−3 SVICC = 7.07x10−4 SVICC 15.208 VT ⎛ IC1 IS 2 ⎞ 0.025V ⎛ IC 2 7IS1 ⎞ ⎜ ln ⎟= ⎜ ln ⎟ = 11.3 µA R ⎝ IC 2 IS1 ⎠ 4.3kΩ ⎝ IC 2 IS1 ⎠ = IC 5 = IC 6 = IC1 = 11.3 µA | IC 3 = IC 7 = IC 2 = 11.3 µA (a) IC1 = IC 2 set by Q 4 and Q 3 IC1 = IC 2 = 11.3 µA | IC 4 (b) No change. | IC 2 = The currents are independent of the areas of Q5 , Q6, and Q7 . ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-117 15.209 (a) The M 3 - M 4 current mirror forces ID1 = 1.5ID 2 . VGS1 − VGS 2 = ID 2 R | ID 2 R = VTN + 2ID1 2ID 2 − VTN − ' 10K n 30K n' ⎛ ⎞ 1 ⎛ 3ID 2 2ID 2 ⎞ 2ID 2 3ID 2 1 ⎜ ⎟ ID 2 = ⎜ − − ⎟= 30K n' ⎠ 3300 ⎜⎝ 10(25x10−6 ) R ⎝ 10K n' 30(25x10−6 )⎟⎠ 57.9 ID 2 = ⇒ ID 2 = 308 µA ID1 = 462 µA 3300 ID 4 = ID 5 = ID 6 = ID1 = 462 µA | ID 3 = ID 7 = ID 2 = 308 µA (b) With λ = 0, the currents do not depend upon the W/L ratios of M5 , M 6 or M 7 as long as all transistors remain in the active region. For λ ≠ 0, there will be a weak dependence, since the drain - source voltages of M2 and M 3 will change slightly. 15.210 *Problem 15.210 - MOS reference current cell VDD 1 0 DC 15 AC 1 M3 3 2 1 1 PFET W=10U L=1U M4 2 2 1 1 PFET W=15U L=1U M5 4 3 2 2 PFET W=10U L=1U M6 4 4 6 6 NFET W=10U L=1U M7 3 4 5 5 NFET W=10U L=1U M1 6 6 0 0 NFET W=10U L=1U M2 5 6 7 7 NFET W=30U L=1U R 7 0 3.3K *.MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0 *.MODEL PFET PMOS KP=10U VTO=-0.75 LAMBDA=0 .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.017 .MODEL PFET PMOS KP=10U VTO=-0.75 LAMBDA=0.017 .OP .AC LIN 1 1000 1000 .PRINT AC ID(M1) ID(M2) .END Results: ID2 = 265 µA ID1 = 377 µA These differ from the hand calculations due to the nonzero value of λ. Simulation with λ = 0 gives results very close to the hand calculations. D2 D2 = 9.82 x 10−4 SVI DD = 6.99 x 10−4 SVI DD 15-118 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.211 The M 3 - M 4 current mirror forces I D1 = I D2. ⎛ 2I D1 ⎞ ⎛ 2I D2 ⎞ ⎟ ⎜ ⎟ VGS1 − VGS 2 = I D2 R | I D2 R = ⎜⎜VTN + − V + TN 10Kn' ⎟⎠ ⎜⎝ 30Kn' ⎟⎠ ⎝ ⎛ I D2 1 ⎛ 2I D2 2I D2 ⎞ I D2 1 ⎜ ⎜ ⎟ − − I D2 = ⎜ = ' ' ⎟ − 6 R ⎝ 10Kn 30Kn ⎠ 3300 ⎜ 5 25x10 15 25x10−6 ⎝ 34.1 I D2 = ⇒ I D2 = 107 µA I D1 = 107 µA 3300 I D 4 = I D5 = I D6 = I D1 = 107 µA | I D3 = I D 7 = I D2 = 107 µA ( ) ( ⎞ ⎟ ⎟ ⎠ ) 15.212 1 g m3 - r o4 v3 + r ο3 icc Current mirror model: 1 Assuming VDS << since it is unknown : gm4 v3 i cc λ ⎛ 50 50 ⎞ ro4 ≅ 2(5x10−4 )(10−4 )⎜ -4 = 0.316mS (250kΩ) = 79.1 -4 ⎟ 2 ⎝ 10 10 ⎠ Acd is determined by the mirror ratio error : icc g − g + go3 1 = icc m 3 m 4 = icc for gm 3 = gm 4 icc + gm 4 v 3 = icc - gm 4 gm 3 + go3 gm 3 + go3 µf 3 +1 Add = gm1 (ro2 ro4 ) ≅ gm1 This error current goes through ro4 to produce the output voltage since the common - mode output resistance at the drain of M2 is very large : v od = icc icc = v ic gm1 1 ≅ v ic 2RSS 1+ 2gm1RSS CMRR = | Acd = ro4 µf 3 + 1 ⎤ 500kΩ 1 ⎛ ro4 ⎞ ⎡ 1 = 6.28 x 10−5 ⎥ ⎜ ⎟=⎢ µ f 3 + 1 ⎝ 2RSS ⎠ ⎣2(79.1) + 1⎦ 50MΩ 79.1 = 1.26 x 10 6 (122 dB) 6.28x10 -5 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-119 15.213 *Problem 15.213 - MOS Amplifier with Active Load VDD 1 0 DC 10 VSS 5 0 DC -10 V1 6 8 DC 0 AC 0.5 V2 7 8 DC 0 AC -0.5 VIC 8 0 DC 0 M3 2 2 1 1 PFET W=50U L=1U M4 3 2 1 1 PFET W=50U L=1U M1 2 6 4 4 NFET W=20U L=1U M2 3 7 4 4 NFET W=20U L=1U ISS 4 5 DC 199.5U RSS 4 5 25MEG .MODEL NFET NMOS KP=25U VTO=1 LAMBDA=0.02 .MODEL PFET PMOS KP=10U VTO=-1 LAMBDA=0.02 .OP .AC LIN 1 1000 1000 .PRINT AC VM(3) VP(3) .TF V(3) VIC .END Results: Adm = 98.8 Acd = 6.16 x10-5. The results are similar to hand calculations. The discrepancies result from not including VDS in the hand calculations for both gm and ro. 15-120 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.214 - 1 r o4 v3 g m3 + gm4 v3 r ο3 i cc icc Current mirror model: Assuming VDS << 1 λ since it is unknown : Add = gm1 (ro2 ro4 ) ≅ gm1 ⎛ 66.7 ro4 66.7 ⎞ = 0.707mS (66.7kΩ) = 47.2 ≅ 2(5x10−4 )(5x10−4 )⎜ −4 −4 ⎟ 2 ⎝ 5x10 5x10 ⎠ Acd is determined by the mirror ratio error : icc g − g + go3 1 icc + gm 4 v 3 = icc - gm 4 = icc m 3 m 4 = icc for gm 3 = gm 4 gm 3 + go3 gm 3 + go3 µf 3 +1 This error current goes through ro4 to produce the output voltage since the common - mode output resistance at the drain of M2 is very large : v od = icc icc = v ic gm1 1 ≅ v ic 2RSS 1+ 2gm1RSS CMRR = | Acd = ro4 µf 3 + 1 ⎤ 133kΩ 1 ⎛ ro4 ⎞ ⎡ 1 = 6.97 x 10−5 = ⎢ ⎥ ⎜ ⎟ µ f 3 + 1 ⎝ 2RSS ⎠ ⎣2(47.2) + 1⎦ 20MΩ 47.2 = 6.77 x 10 5 (117 dB) -5 6.97x10 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-121 15.215 *Problem 15.214 - MOS Amplifier with Active Load VDD 1 0 DC 12 VSS 5 0 DC -12 V1 6 8 DC 0 AC 0.5 V2 7 8 DC 0 AC -0.5 VIC 8 0 DC 0 M3 2 2 1 1 PFET W=50U L=1U M4 3 2 1 1 PFET W=50U L=1U M1 2 6 4 4 NFET W=20U L=1U M2 3 7 4 4 NFET W=20U L=1U ISS 4 5 DC 1M RSS 4 5 10MEG .MODEL NFET NMOS KP=25U VTO=1 LAMBDA=0.02 .MODEL PFET PMOS KP=10U VTO=-1 LAMBDA=0.02 .OP .AC LIN 1 1000 1000 .PRINT AC VM(3) VP(3) .TF V(3) VIC .END Results: Adm = 56.2 Acd = 6.82 x10-5. The results are similar to hand calculations. The discrepancies result from not including VDS in the hand calculations for gm and ro. 15-122 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.216 Assuming VCE << VA since it is unknown : ⎛ 60 60 ⎞ r Add = g m2 ro2 ro4 ≅ g m2 o4 ≅ 40 10−4 ⎜ -4 = 4.00mS (300kΩ)= 1200 -4 ⎟ 2 ⎝ 10 10 ⎠ Acd : This circuit is often the input stage of a feedback amplfier and the feedback ( ) ( ) applies an offset voltage Vos that forces vC1 = vC 2 . In this case, the induced collector current imbalance exactly matches the current mirror imbalance and Acd = 0. The case for VC1 ≠ VC2 is a more difficult problem! The mirror ratio causes a mismatch in the collector currents and therefore ∆g m ∆g g m2 = g m − m | The common - mode voltage that is 2 2 cm vπ is multiplied by g m1 and g m2. The common g mvπcm term a mismatch in g m : g m1 = g m + developed across rπ 1 and rπ 2 ( ) is canceled out by the current mirror, but the mismatch terms add at the output of the current mirror. The output voltage is given approximately by ( ) vo = ∆g m2vπcm ro4 ro2 = ∆g m2vπcm vπcm = v ic Acd = rπ 2 ( rπ 2 + (β o + 1) 2R1 ro2 ) ro2 ∆g m2 cm µ f 2 = vπ 2 g m2 2 ≅ v ic ( 1 g m2 2R1 ro2 ) ≅ vic v = ic for 2R1 >> ro2 g m2ro2 µ f 2 vo 1 ∆g m2 ≅ v ic 2 g m2 The collector current imbalance can be found as follows : Assume that VEC 4 = VEC 3 + ∆V 0.7 + ∆V ⎛ ∆V ⎞ VA 60V VA and equal Early voltages : IC 4 = IC 2 ⇒ IC1 = IC1⎜1− = = 0.48V ⎟ | ∆V ≅ 2 0.7 β F 125 VA ⎠ ⎝ 1+ + β F VA ⎛ V ⎞ ⎛ V − ∆V ⎞ ∆V V | IC 0 = I S exp BE ≅ IC ∆IC = IC1 − IC2 = IC 0 ⎜1+ C1 ⎟ − IC0 ⎜1+ C1 ⎟ = IC 0 VT VA ⎠ VA ⎝ VA ⎠ ⎝ 1+ ∆IC = IC 0 Acd = ∆V ∆V ≅ IC VA VA | ∆IC ∆V 1 ≅ = IC VA β F | ∆g m2 ∆IC 1 = = g m2 IC βF | Acd = 1 2β F 1 1200 = 4x10-3 | CMRR = = 3x105 (110 dB) -3 2(125) 4x10 Note that VOS ≅ ∆V Add | ∆V ≅ 60 0.48 = 0.48V | VOS ≅ = 0.400 mV 125 1200 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-123 15.216 cont. For VIC : VCB1 = VCC − VEB3 − VIC ≥ 0 | VCC ≥ VIC + VEB3 = 1.5 + 0.7 = 2.2 V Assume that the current source needs VCS = 0.7 V across it to operate properly. VIC − VBE − (−VEE ) ≥ VCS | VEE ≥ VCS + VBE − VIC = 0.7 + 0.7 − (−1.5) = 2.9V We need ± 2.9 - V supplies or approximately ± 3V. These results can be easily checked with SPICE - See Problem 15.217 15.217 *Figure 15.83 - BJT Differential Amplifier with Active Load VCC 1 0 DC 5 VEE 5 0 DC -5 Q4 3 2 1 PBJT 1 Q3 2 2 1 PBJT 1 Q1 2 6 4 NBJT 1 Q2 3 7 4 NBJT 1 *Apply offset voltage to balance collector voltages V1 6 8 DC 0.4107M AC 0.5 *V1 6 8 DC 0 AC 0.5 V2 7 8 DC 0 AC -0.5 VIC 8 0 DC 0 I1 4 5 199.8U R1 4 5 25MEG .MODEL NBJT NPN BF=125 VA=60 .MODEL PBJT PNP BF=125 VA=60 .OP .AC LIN 1 1000 1000 .PRINT AC VM(3) VP(3) VM(4) VP(4) .TF V(3) VIC .END Results: Adm = 1200 Acd = 5.11x10-6. CMRR = 167 dB. The results are similar to hand calculations. Note that a very high CMRR is achieved when the circuit is brought back to balance, as is the case in operational amplifier input stages with feedback applied. For the case with no offset voltage applied, Acd = 3.73x10-3, and ∆V = 0.49 V. These agree well with the analysis in Prob. 15.216. The value of the required offset voltage is also very similar to the hand calculations. 15-124 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.218 (a ) Assuming VCE << VA since it is unknown : ( ) Add = g m2 ro2 ro4 ≅ g m2 ⎛ 75 ro4 75 ⎞ ≅ 40 5x10−5 ⎜ = 2.00mS (750kΩ)= 1500 −5 −5 ⎟ 2 ⎝ 5x10 5x10 ⎠ ( ) Acd : This circuit is often the input stage of a feedback amplfier and the feedback applies an offset voltage Vos that forces vC1 = vC 2 . In this case, the induced collector current imbalance exactly matches the current mirror imbalance and Acd = 0. The case for VC1 ≠ VC2 is a more difficult problem! The mirror ratio causes a mismatch in the collector currents and therefore ∆g m ∆g g m2 = g m − m | The common - mode voltage that is 2 2 cm vπ is multiplied by g m1 and g m2 . The common g mvπcm term a mismatch in g m : g m1 = g m + developed across rπ 1 and rπ 2 ( ) is canceled out by the current mirror, but the mismatch terms add at the output of the current mirror. The output voltage is given approximately by ( ) vo = ∆g m2vπcm ro4 ro2 = ∆g m2vπcm vπcm = v ic Acd = rπ 2 ( rπ 2 + (β o + 1) 2R1 ro2 ) ro2 ∆g m2 cm µ f 2 = vπ 2 g m2 2 ≅ v ic ( 1 g m2 2R1 ro2 ) ≅ vic v = ic for 2R1 >> ro2 g m2ro2 µ f 2 vo 1 ∆g m2 ≅ v ic 2 g m2 The collector current imbalance can be found as follows: Assume that VEC 4 = VEC 3 + ∆V 0.7 + ∆V ⎛ ∆V ⎞ 75V V VA = IC 2 ⇒ IC1 = IC1⎜1− = 0.60V | ∆V ≅ A = ⎟ 2 0.7 β F 125 ⎝ VA ⎠ 1+ + β F VA 1+ and equal Early voltages: IC 4 ⎛ V ⎞ ⎛ V − ∆V ⎞ V ∆V ∆IC = IC1 − IC 2 = IC 0 ⎜1+ C1 ⎟ − IC 0 ⎜1+ C1 | IC 0 = IS exp BE ≅ IC ⎟ = IC 0 VA ⎠ VA VT ⎝ VA ⎠ ⎝ ∆V ∆V ∆IC ∆V 1 ∆gm 2 ∆IC 1 1 ∆IC = IC 0 ≅ IC | ≅ = | = = | Acd = IC gm 2 IC βF VA VA VA β F 2β F 1 1500 = 4 x10 -3 | CMRR = = 3.75x10 5 (112 dB) -3 2(125) 4 x10 15.218 continued on next page Acd = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-125 15.218 cont. Note that VOS ≅ ∆V Add | ∆V ≅ 75 0.60 = 0.60V | VOS ≅ = 0.400 mV 125 1500 For VIC : VCB1 = VCC − VEB 3 − VIC ≥ 0 | VCC ≥ VIC + VEB 3 = 1.5 + 0.7 = 2.2 V Assume that the current source needs VCS = 0.7 V across it to operate properly. VIC − VBE − (−VEE ) ≥ VCS | VEE ≥ VCS + VBE − VIC = 0.7 + 0.7 − (−1.5) = 2.9V We need ± 2.9 - V supplies or approximately ± 3V. ( ) (b) Add = g m2 ro2 ro4 ≅ g m2 ⎛ 100 ro4 100 ⎞ ≅ 40 5x10−5 ⎜ = 2.00mS (1.00 MΩ) = 2000 −5 −5 ⎟ 2 ⎝ 5x10 5x10 ⎠ ( ) 0.7 + ∆V ⎛ ∆V ⎞ v 1 ∆g m2 VA 100V VA | IC 4 = IC 2 ⇒ IC1 = IC1⎜1− = = 0.80V Acd = o ≅ ⎟ | ∆V ≅ 2 0.7 VA ⎠ 125 v ic 2 g m2 βF ⎝ 1+ + β F VA ⎛ V ⎞ ⎛ V − ∆V ⎞ V ∆V | IC0 = I S exp BE ≅ IC ∆IC = IC1 − IC2 = IC 0 ⎜1+ C1 ⎟ − IC0 ⎜1+ C1 ⎟ = IC 0 VA ⎠ VA VT ⎝ VA ⎠ ⎝ ∆IC ∆V 1 ∆g m2 ∆IC 1 1 ∆V ∆V ∆IC = IC 0 ≅ IC | ≅ = | = = | Acd = VA β F 2β F VA VA IC g m2 IC βF 1+ Acd = 1 2000 = 4x10-3 | CMRR = = 5.00x105 (114 dB) -3 2(125) 4x10 For VIC : VCB1 = VCC − VEB 3 − VIC ≥ 0 | VCC ≥ VIC + VEB 3 = 1.5 + 0.7 = 2.2 V Assume that the current source needs VCS = 0.7 V across it to operate properly. VIC − VBE − (−VEE )≥ VCS | VEE ≥ VCS + VBE − VIC = 0.7 + 0.7 − (−1.5) = 2.9V We need ± 2.9 - V supplies or approximately ± 3V. 15.219 Results: For VA = 75 V, Adm = 1470 and Acd = 6.92x10-3. CMRR = 106 dB. The results are similar to hand calculations. Note that a very high CMRR is achieved when the circuit is brought back to balance (with VOS = 0.728mV), as is the case in operational amplifier input stages with feedback applied. For the case with the offset voltage applied, Acd = 2.71x10-7. 15-126 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.220 (a) I D5 = I D 4 = I D3 = I D2 = I D1 = I SS = 100 µA 2 ( ) −4 2 10 2I D1 = 0.75 + = 1.20V VGS 2 = VGS1 = VTN + Kn1 40 2.5x10−5 ( ) ( ) ( ) 2 10−4 2I D 4 VGS 5 = VGS 4 = VGS 3 = VTP − = −0.75 − = −1.25V | VDS 3 = VDS 4 + VGS 5 = −2.50V K p4 80 10−5 VDS1 = VDS 2 = 10 + VGS 4 + VGS 5 − (−VGS1 )= 8.70V | VDS 5 = VDS 4 = VGS 4 = −1.25V Q − Pts : (100µA,8.70V ) (100µA,8.70V ) (100µA,-2.50V ) (100µA,-1.25V ) (100µA,-1.25V ) (b) A dd ⎛ 2 ⎞ = g m2 ⎜ ro2 µ f 3ro5 ⎟ ≅ g m2ro2 ⎝ 3 ⎠ ⎛ 1 ⎞ + 8.7 ⎟ ⎜ Add = 2(40) 2.5x10−5 10−4 1+ 0.017(8.7) ⎜ 0.017 −4 ⎟ = 0.479mS (675kΩ) = 323 10 ⎜ ⎟ ⎝ ⎠ (Note that the loop - gain of the Wilson source is reduced by the presence of Rout1 ≅ 2ro1.) ⎛ 1 ⎞ + 1.25⎟ ⎜ (c) Add = g m1 ro1 ro3 | ro3 = ⎜ 0.01710−4 ⎟ = 601kΩ ⎜ ⎟ ⎝ ⎠ ( )( )[ ( ] ) ( ) Add = 0.479mS 675kΩ 601kΩ = 152 - The Wilson source yields a 2X improvement. 15.221 M 1 2 3 4 5 ID(µA) 101 99.0 101 99.0 99.0 VDS 8.69 7.33 -2.48 -1.24 -2.60 (V) Results: Adm = 313. The gain and Q-points are similar to hand calculations. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-127 15.222 ID 2 = ID1 = I1 I = 125 µA | ID 3 = ID 4 = ID 5 = ID 6 = ID 7 = I2 − 1 = 125 µA 2 2 2(1.25x10−4 ) 2ID = 0.75 + = 1.25V For the NMOS transistors VGS = VTN + Kn 40(2.5x10−5 ) 2(1.25x10−4 ) 2ID For the PMOS transistors VGS = VTP − = −0.75 − = −1.54V Kp 40(10−5 ) VDS1 = VDS 2 = −VGS 3 = 1.54V | VDS 7 = VDS 6 = VGS 6 = 1.25V | VDS 5 = VGS 6 + VGS 7 = 2.50V VDS 4 = VDS 3 = (−5 + VDS 5 ) − (−VGS1 − VGS 3 ) = −5 + 2.50 − (−1.25 + 1.54) = −2.79V Q − Pts : (125µA,1.54V) (125µA,1.54V) (125µA,-2.79V) (125µA,-2.79V) (125µA,2.50V) (125µA,1.25V) (125µA,1.25V) M3 v id M1 2 RL (b) Add = gm 2 (µ f 4 ro2 µ f 5 ro7 )≅ µ f 2µ f 4 2 ⎞ ⎛ 1 + 1.54 ⎟ ⎜ gm 2 = 2(40)(2.5x10−5 )(1.25x10−4 )[1+ 0.017(1.54 )] = 0.507mS | ro3 = ⎜ 0.017 −4 ⎟ = 483kΩ ⎜ 1.25x10 ⎟ ⎠ ⎝ ⎞ ⎛ 1 + 2.79 ⎟ ⎜ gm 4 = 2(40)(10−5 )(1.25x10−4 )[1+ 0.017(2.79)] = 0.324mS | ro4 = ⎜ 0.017 −4 ⎟ = 493kΩ ⎜ 1.25x10 ⎟ ⎠ ⎝ Add ≅ µ f 2µ f 4 15-128 2 = (0.507mS)(483kΩ)(0.324mS )(493kΩ) = 19600 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.223 *Figure P15.222 - CMOS Folded Cascode Amplifier with Active Load VDD 1 0 DC 5 VSS 10 0 DC -5 *An offset voltage must be applied to bring output to -2.5V V1 4 11 DC -5.085M AC 0.5 V2 5 11 DC 0 AC -0.5 VIC 11 0 DC 0 M1 2 4 6 6 NFET W=40U L=1U M2 3 5 6 6 NFET W=40U L=1U M3 8 6 2 2 PFET W=40U L=1U M4 7 6 3 3 PFET W=40U L=1U M5 8 9 10 10 NFET W=40U L=1U M6 9 9 10 10 NFET W=40U L=1U M7 7 8 9 9 NFET W=40U L=1U I2A 1 2 DC 250U I2B 1 3 DC 250U I1 6 10 DC 250U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.017 .MODEL PFET PMOS KP=10U VTO=-0.75 LAMBDA=0.017 .OP .AC LIN 1 1000 1000 .PRINT AC VM(7) VP(7) VM(6) VP(6) VM(8) VP(8) .TF V(7) VIC .END 8 Results: Add = 23700, Acd = 1.81x10-4. Rout = 47.7 MΩ, CMRR = 1.31 x 10 . The values of Add and Rout are similar to hand calculations. Acd and the CMRR are limited by the small residual mismatches in device parameters. From Problem 15.222, g m2 = 0.507mS | ro3 = 483kΩ | g m4 = 0.324mS | ro4 = 493kΩ Rout = µ f 4ro2 µ f 5ro7 ≅ µ f 4ro2 2 = 0.324mS (493kΩ)(493kΩ) 2 = 39.4 MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-129 15.224 M M 1 M 2 +5 V 3 25 1 25 1 I2 25 1 I2 R I1 M M 1 10 1 -5V 2 10 1 Using a reference current of 250µA and 1:1 current mirrors with − VGSP = VGSN : −VGSP = VGSN = VTN + 2(2.5x10−4 ) 2ID 10 − 2.16 − 2.16 V = 0.75 + = 2.16V | R = = 22.7kΩ −6 Kn 2.5x10−4 A 10(25x10 ) 15.225 ⎛ R ⎞ VBE 2 R2 = VBE 2 ⎜1+ 2 ⎟ R1 ⎝ R1 ⎠ ⎛ VBE 2 ⎞ ⎜ 200µA − R ⎟ 1 ⎟ | VBE 2 = 0.025ln⎜ 10 fA ⎜ ⎟ ⎜ ⎟ ⎝ ⎠ For β F = ∞, IB = 0. | VBE 3 + VEB 4 = VBE 2 + ⎛ 200µA − I1 ⎞ VBE 2 VBE 2 = 0.025ln⎜ ⎟ | I1 = R1 ⎝ 10 fA ⎠ ⎛ VBE 2 ⎞ ⎜ 200µA − 20kΩ ⎟ 0.589 = 171µA VBE 2 = 0.025ln⎜ ⎟ → VBE 2 = 0.589V | IC 2 = 200µA − 20kΩ 10 fA ⎜ ⎟ ⎝ ⎠ ⎛ 20kΩ ⎞ 1 Since IS 4 = IS 3 , VBE 3 = VEB 4 = (0.589)⎜1+ ⎟ = 0.589V and IC 4 = IC 3 = 171 µA. ⎝ 20kΩ ⎠ 2 15-130 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.226 (a) β F = ∞ : VBE 3 + VEB 4 = VBE1 + VEB 2 VT ln IO IO I2 I2 +VT ln - V ln - V ln =0 AE 3 AE 4 T AE1 T A ISON ISOP ISON ISOP E 2 AEO AEO AEO AEO 2 ⎡ IO2 AE1 AE 2 IO2 AEO ISON ISOP AE1 AE 2 ⎤ AE 3 AE 4 VT ln⎢ = 0 → = 1 | IO = I2 ⎥ 2 2 2 I2 AEO I2 AE 3 AE 4 AE1 AE 2 ⎣ ISON ISOP AE 3 AE 4 ⎦ (b) IO = 300µA AE 3 AE 4 = 100 µA 3AE 3 3AE 4 15.227 (a) I D8 = I REF = 250µA | I D10 = I D9 = 2I D8 = 500µA I D1 = I D2 = I D3 = I D 4 = 2(250µA) I D9 = 250µA | VDS 8 = VGS 8 = 0.75 + = 2.16V 2 10 25x10−6 ( I D5 = I D11 = I D10 = 500µA | VGS11 = 0.75 + V VGS 6 = −VGS 7 = GS11 = 1.789V | I D 7 = I D6 2 −VDS 4 = −VDS 3 = −VGS 3 = VGS 2 = VTN + 2(500µA) ) = 3.58V ( ) 10(25x10 ) = (1.789 − 0.75) = 135µA 5 25x10−6 −6 2 2 2(250µA) 2I D2 = 0.75 + = 1.75V Kn2 20 25x10−6 ( VDS1 = VDS 2 = 5 − VSD 4 − (−VGS 2 )= 5.00V | VDS10 = −VDS 5 = 5 − ) VGS11 = 3.21V 2 VDS 6 = −VDS 7 = 5.00V | VDS 9 = 5 − VGS 2 = 5 −1.75 = 3.25V ID (µA) VDS (V) SPICE ID (µA) VDS (V) 1 2 3 4 5 6 7 8 9 10 11 250 250 250 250 500 135 135 250 500 500 500 5.00 5.00 -1.75 -1.75 -3.21 5.00 -5.00 2.16 3.25 3.21 3.58 255 4.97 255 4.99 255 -1.74 255 -1.73 509 -3.24 139 5.01 139 -5.00 250 2.14 509 3.28 509 3.23 509 3.52 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-131 (b) Adm = Avt1 Avt 2 Avt 3 = [gm 2 (ro2 ][ ] ro4 ) gm 5 (ro5 ro12 ) [1] gm 2 = 2(20)(25x10−6 )(2.50x10−4 )[1+ 0.017(5.00)] = 0.521mS 1 58.8 + 5.00 V 58.8 + 1.75 V = 58.8V | ro2 = = 255kΩ | ro4 = = 242kΩ | AV1 = 64.7 −4 λ 0.017 A 2.5x10 2.5x10−4 A 58.8 + 3.21 V gm 5 = 2(100)(10−5 )(5.00x10−4 )[1+ 0.017(3.21)] = 1.03mS | ro12 = ro5 = = 124kΩ 5.00x10−4 A Avt 2 = 63.9 | Adm = Avt1 Avt 2 Avt 3 = [64.7] [63.9] [1] = 4130 1 = (c ) The amplification factor is inversely proportional to the square root of current. Thus, ⎡ 64.7⎤ ⎡ 63.9 ⎤ Adm = Avt1 Avt 2 Avt 3 ≅ ⎢ [1] = 2065 ⎣ 2 ⎥⎦ ⎢⎣ 2 ⎥⎦ SPICE Results: Adm = 4000, Acm = 0.509, Rout = 1.81 kΩ. 15.228 Adm ≅ µ f 2µ f 5 4 | For the MOSFET, µ f 2 ∝ But, ID 2 ∝ IREF and ID 5 ∝ IREF → Adm ∝ (a) Adm = 16000 100µA = 6400 250µA (b) 1 ID ∴ Adm ∝ 1 ID 2 1 ID 5 1 IREF Adm = 16000 100µA = 80000 20µA 15.229 Adm = Av1 Av 2 Av 3 = gm 2 (ro2 ro4 ) gm 5 (ro5 ro12 ) [1] [ ][ ] ID10 = IREF =100µA | ID12 = ID11 = 2ID10 = 200µA | ID1 = ID 2 = ID 3 = ID 4 = ID 5 = ID12 = 200µA | VDS 4 = VGS 3 = −VGS 2 = −VTN − ID11 = 100µA 2 2(100µA) 2IDS 2 = −0.75 − = −1.38V Kn2 20(25x10−6 ) VDS 2 = 10 + VDS 4 − (−VGS 2 ) = 10.0V | gm 2 = 2(20)(25x10−6 )(100µA)[1+ 0.017(10)] = 0.342mS 1 λ = 1 58.8 + 10 V 58.8 + 1.38 V = 58.8V | ro2 = = 688kΩ | ro4 = = 602kΩ | Av1 = 110 −4 0.017 10 A 10−4 A VDS12 = −VDS 5 = 10 − VGSGG 2 | VGSGG = 0.75 + 2(200µA) = 2.54V | VDS12 = −VDS 5 = 8.73V 5(25x10−6 ) gm 5 = 2(100)(10−5 )(2x10−4 )[1+ 0.017(8.73)] = 0.678mS | ro12 = ro5 = Av 2 = 115 | Adm = Av1 Av 2 Av 3 = [110] [115] [1] = 12600 58.8 + 8.73 V = 338kΩ 2x10−4 A Adm = 10900 if (1 + λVDS ) is neglected in the gm calculation. 15-132 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.230 *Figure P15.229 - CMOS Amplifier with Active Load VDD 8 0 DC 10 VSS 14 0 DC -10 *An offset voltage is used to set Vo to approximately zero volts. V2 1 15 DC 0.3506M AC 0.5 V1 2 15 DC 0 AC -0.5 VIC 15 0 DC 0 M1 3 1 5 14 NFET W=20U L=1U M2 4 2 5 14 NFET W=20U L=1U M3 3 3 8 8 PFET W=50U L=1U M4 4 3 8 8 PFET W=50U L=1U M5 6 4 8 8 PFET W=100U L=1U *The offset can be adjusted to zero by correcting the value of W/L *M5 6 4 8 8 PFET W=89.5U L=1U M6 8 6 13 14 NFET W=10U L=1U M7 14 7 13 8 PFET W=25U L=1U MGG 6 6 7 14 NFET W=5U L=1U M10 9 9 14 14 NFET W=10U L=1U M11 5 9 14 14 NFET W=20U L=1U M12 7 9 14 14 NFET W=20U L=1U IREF 0 9 DC 100U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.017 .MODEL PFET PMOS KP=10U VTO=-0.75 LAMBDA=0.017 *.MODEL NFET NMOS KP=25U VTO=0.75 GAMMA=0.6 LAMBDA=0.017 *.MODEL PFET PMOS KP=10U VTO=-0.75 GAMMA=0.75 LAMBDA=0.017 .OP .AC LIN 1 1000 1000 .PRINT AC VM(13) VP(13) VM(4) VP(4) .TF V(13) VIC .END Results: Adm = 11200, Acm = 0.604, Rout = 3.10 kΩ. (a) 1 2 3 4 5 6 7 GG 10 11 12 IDS (µA) 112 112 112 112 223 44.2 44.2 223 100 223 223 VDS (V) 9.96 9.99 -1.41 -1.37 -8.70 10.0 -10.0 -2.60 1.63 8.63 8.70 (b) IDS (µA) 110 110 110 110 219 0 0 219 100 219 219 VDS (V) 11.2 11.2 -1.40 -1.37 -8.85 10.0 -9.97 -3.79 1.63 7.41 7.35 Note that the body effect has increased the threshold voltages of M6 and M7 to the point that they are no longer conducting. VTN6 = 2.24 V and VTP7 = -2.61V. The W/L ratio of MGG needs to be redesigned to solve this problem. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-133 15.231 ID10 = IREF = 250µA | ID11 = 2ID10 = 500µA | ID12 = 4ID10 = 1000µA ID1 = ID 2 = ID 3 = ID 4 = 2(250µA) ID11 = 250µA | VDS10 = VGS10 = 0.75 + = 2.16V 2 10(25x10−6 ) ID 5 = IDGG = ID12 = 1000µA | VGSGG = 0.75 + 2(1000µA) = 4.75V 5(25x10−6 ) 10(25x10 V VGS 6 = −VGS 7 = GSGG = 2.375V | ID 7 = ID 6 = 2 2 VDS 4 = VDS 3 = VGS 3 = −VGS 2 = −VTN − −6 )(2.375 − 0.75) 2 = 330µA 2(250µA) 2ID 2 = −0.75 − = −1.75V Kn2 20(25x10−6 ) VDS1 = VDS 2 = 7.5 + VDS 4 − (−VGS 2 ) = 7.50V | VDS12 = −VDS 5 = 7.5 + VGSGG = 5.13V 2 VDS 6 = −VDS 7 = 7.5V | VDS11 = 7.5 − VGS 2 = 7.5 −1.75 = 5.75V M IDS (µA) VDS (V) SPICE IDS (µA) VDS (V) 1 2 3 4 5 6 7 GG 10 11 12 250 250 250 250 1000 7.50 7.50 -1.75 -1.75 -5.13 330 7.50 330 1000 250 500 1000 -7.50 4.75 2.16 5.75 5.13 264 266 -264 -266 1050 7.46 7.09 -1.76 -2.14 -5.20 359 7.54 -359 1050 250 530 1050 -7.46 4.69 2.14 5.78 5.11 [ ][ ] Adm = Av1 Av 2 Av 3 = gm 2 (ro2 ro4 ) gm 5 (ro5 ro12 ) [1] gm 2 = 2(20)(25x10−6 )(250µA)[1+ 0.017(7.50)] = 0.531mS 1 58.8 + 7.50 V 58.8 + 1.75 V = 58.8V | ro2 = = 265kΩ | ro4 = = 242kΩ | Av1 = 67.2 −4 A λ 0.017 2.5x10 2.5x10−4 A 58.8 + 5.13 V = 63.9kΩ gm 5 = 2(100)(10−5 )(10−3 )[1+ 0.017(5.13)] = 1.48mS | ro12 = ro5 = 10−3 A Av 2 = 47.3 | Adm = Av1 Av 2 Av 3 = [67.2] [47.3] [1] = 3180 1 = SPICE Results: Adm = 2950, Acm = 0.03, Rout = 1.10 kΩ. 15-134 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.232 (a) For saturation of M11 : VDS11 = 0 − VGS 2 − (−VSS ) = VSS − VGS 2 ≥ VGS 2 = VTN + 2(200µA) 2IDS11 = = 0.894 K n11 20(25x10−6 ) 2(100µA) 2IDS 2 = 0.75 + = 1.38V | VSS −1.38 ≥ 0.894 → VSS ≥ 2.27V Kn 2 20(25x10−6 ) For saturation of M12 : VDS12 = 0 − 2(200µA) VGSGG V 2ID12 − (−VSS ) = VSS − GSGG ≥ = = 0.894 2 2 K n12 20(25x10−6 ) VGSGG = 0.75 + 2(200µA) 2.54 = 2.54V | VSS − ≥ 0.894 → VSS ≥ 2.16V −6 2 5(25x10 ) For saturation of M1 and M 2 : VDS1 = VDD + VGS 3 − (−VGS1 ) = VDD + VGS 3 +VGS1 ≥ 2(100µA) 2ID1 = = 0.633 K n1 20(25x10−6 ) VGS 3 = −VGS1 : VDD ≥ 0.633V For saturation of M 5 : −VDS 5 = VDD − 2(200µA) 2.54 2ID 5 ≥ = = 0.633V → VDD ≥ 1.90V K p5 2 100(10x10−6 ) M 6 and M 7 are always saturated : e.g. VDS 6 ≥ VGS 6 The minimum supply voltages are : VDD ≥ 1.90V VSS ≥ 2.27V For the symmetrical supply case, VDD = VSS ≥ 2.27V (b) The values of VDD and VSS in part (a) do not provide any significant common - mode input voltage range. For saturation of M11 with VIC = −5V, VDS11 = VIC − VGS 2 − (−VSS ) = VSS −1.38 − 5 ≥ 0.894 → VSS ≥ 7.27V For saturation of M1 and M 2 : VDS1 = VDD − VSG 3 − (VIC − VGS1) = VDD − 5 −1.38 +1.38 ≥ 0.633 → VDD ≥ 5.63V For an output range of 5V, saturation of M12 requires V 2.54 ≥ 0.894 → VSS ≥ 7.25V VDS12 = −5 − GSGG − (−VSS ) = VSS − 5 − 2 2 For Saturation of M 5 : 2.54 − 5 ≥ 0.633V → VDD ≥ 6.90V VSD 5 = VDD − 2 The minimum supply voltages are : VDD ≥ 6.90V VSS ≥ 7.25V For the symmetrical supply case, VDD = VSS ≥ 7.25V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-135 15.233 ID 9 = ID10 = ID12 = ID11 = IREF = 250µA | ID 6 = ID 7 = ID 8 = 3ID12 = 750µA ID1 = ID 2 = ID13 = ID 5 = ID 3 = ID 4 = ID 9 = 125µA 2 VDS10 = VDS12 = VDS11 = VGS12 = VTN + VGS1 = 0.75 + 2(250µA) 2ID12 = 0.75 + = 2.75V K n12 5(25x10−6 ) 2(125µA) = 1.25V | VDS 9 = −VGS1 − (−10 + VGS12 ) = 6V 40(25x10−6 ) VDS 7 = VO − (−10 + VGS12 + VGS11 − VGS 7 ) = 0 + 10 − 2.75 − 2.75 + 0.75 + 2(750µA) = 7.25V 15(25x10−6 ) VDS 8 = 10 − VDS 7 = 2.75V VDS 6 = −(10 − VO ) = −10V + 0 = −10V | VDS 5 = VDS13 = VDS 3 = VDS 4 = −0.75 − 2(125µA) = −1.31V 80(10x10−6 ) M 1 2 3 4 5 6 7 8 9 10 11 12 13 ID (µA) 125 125 125 125 125 750 750 750 250 250 250 250 125 VDS (V) 8.63 8.63 -1.31 -1.31 -1.31 -10 7.25 2.75 6.00 2.75 2.75 2.75 -1.31 K n' ⎛ W ⎞ 10−5 ⎛ W ⎞ 2 2 ⎜ ⎟ (−VDS 4 − VDS 5 + 0.75) = 750µA (b) ⎜ ⎟ (VGS 6 − VTP ) = 2 ⎝ L ⎠6 2 ⎝ L ⎠6 ⎛W ⎞ 10−5 ⎛ W ⎞ 2 ⎜ ⎟ (−2.62 + 0.75) = 750µA → ⎜ ⎟ = 42.9 ⎝ L ⎠6 2 ⎝ L ⎠6 Add = Av1 Av 2 = (gm 2 ro2 )(gm 6 ro6 ) = µ f 2µ f 6 | µ f 2 ≅ µf 6 ≅ 1 λp 15-136 1 λn 2(40)(25x10−6 ) 2K n 2 1 = = 235 ID 2 125x10−6 0.017 2(42.9)(10x10−6 ) 2K p 6 1 = = 62.9 | Add = 235(62.9) = 14800 ID 6 750x10−6 0.017 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.234 *Figure P15.233 - CMOS Amplifier with Active Load VDD 8 0 DC 10 VSS 14 0 DC -10 *Connect feedback to determine Vos *V1 1 13 DC 0 *The offset voltage must be used to set Vo to approximately zero voltages. V1 1 15 DC 0.4423M AC 0.5 V2 2 15 DC 0 AC -0.5 VIC 15 0 DC 0 M1 3 1 5 5 NFET W=40U L=1U M2 4 2 5 5 NFET W=40U L=1U M3 6 7 8 8 PFET W=80U L=1U M4 7 7 8 8 PFET W=80U L=1U M5 4 3 7 7 PFET W=80U L=1U M6 13 4 8 8 PFET W=42.9U L=1U *The offset can be adjusted to zero by correcting the value of W/L *M6 13 4 8 8 PFET W=37.25U L=1U M7 13 9 12 12 NFET W=15U L=1U M8 12 10 14 14 NFET W=15U L=1U M9 5 9 11 11 NFET W=5U L=1U M10 11 10 14 14 NFET W=5U L=1U M11 9 9 10 10 NFET W=5U L=1U M12 10 10 14 14 NFET W=5U L=1U M13 3 3 6 6 PFET W=80U L=1U IREF 0 9 DC 250U .MODEL NFET NMOS KP=25U VTO=0.75 LAMBDA=0.017 .MODEL PFET PMOS KP=10U VTO=-0.75 LAMBDA=0.017 .OP .AC LIN 1 1000 1000 .PRINT AC VM(13) VP(13) VM(4) VP(4) .TF V(13) VIC .END Results: Vos = 0.4423 mV, Adm = 22500, Acm = 0.2305, CMRR = 99.9 dB, ROUT = 90.3 MΩ. The values of Add and Rout are similar to hand calculations. Acd and the CMRR are limited by the offset induced mismatches in the devices. With the W/L of M6 corrected, Vos ≈ 0, Adm = 20800, A = 9.28 x 10-3. R = 90.3 MΩ, CMRR = 127 dB. cm out ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-137 15.235 +V 25 1 50 1 M8 50 1 M 10 M9 I I REF I M6 12.5 v 10 1 1 M1 1 M2 50 1 2 DD 50 1 2 v M 11 vO M7 1 M5 40 1 25 1 M4 M3 20 1 20 1 -V SS The W/L ratios have been scaled to keep the Q-points and gain the same. Note that the output stage should remain a source follower pair and is not mirrored. 15-138 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.236 A A Q Q 10 Q 9 I I VCC 5A I1 8 2 Q REF A 5A v Q 12 Q 1 2 v 1 3 A O A R L Q 7 2 Q Q v Q 11 5A Q 7 5 AE5 Q 4 A -V EE Note that the output stage should remain complementary emitter − followers. I The gain of the first stage is approximately Av1 = gm1rπ 5 = C1 β o5 , the mirror IC 5 image amplifier with an npn transistor for Q5 will have the highest gain. The voltage gain of the rest of the amplifier is the same. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-139 15.237 VEB 7 + VEB 8 = VEB 6 + VEB 4 = 2VT ln ⎡ 250µA ⎤ IC 4 I = 2VT ln C14 = 0.05ln⎢ ⎥ = 1.142V IS 4 2IS 4 ⎣ 2(15 fA)⎦ VEB 7 + VEB 8 = VT ln I IC 7 I 60 IC 8 IC 8 + VT ln C 8 IC 7 = α F IB 8 = α F C 8 = = IS 7 IS 8 β F 61 60 61 VEB 7 + VEB 8 = VT ln IC 8 IC 8 IC2 8 + VT ln → 0.025ln = 1.142 61(15 fA) 4 (15 fA) 61(15 fA)(4 )(15 fA) IC 8 = 1.946 mA | IC16 ≅ IC 8 | AE16 = IC16 1946µA AE12 = (1) = 7.78 250µA IC12 ⎛ 75µA ⎞ 2(0.5583V ) VBE 6 = VEB10 = 0.025ln⎜ = 574 Ω ⎟ = 0.558V | RBB = 1.946 mA ⎝ 15 fA ⎠ ⎤ ⎡ (β + 1)r o π8 Adm = Av1 Av 2 Av 3 ≅ gm 2 ro2 [rπ 7 + (β o + 1)rπ 8 ] ⎢ gm 8 (ro8 ro16 )⎥ [1] ⎦ ⎣ rπ 7 + (β o + 1)rπ 8 [ { }] [ ( (β o + 1)rπ 8 ⎛ µ f 8 ⎞⎤ 1 ⎜ ⎟⎥ [ ] π 7 + (β o + 1)rπ 8 ⎝ 2 ⎠⎦ 125µA (40)(60 + 4.3) = 3.03 x 10 5 60 Adm = Av1 Av 2 Av 3 ≅ gm 2 ro2 rπ 7 + (β o + 1)rπ 8 [ Rid = 2rπ 1 = 2 15-140 µf 8 ]4 Adm ≅ gm 2 (ro2 2rπ 7 ) ≅ ⎡ )]⎢⎣ r µ IC 2 β o7 f 8 = 31.8µA IC 7 2 2 150(0.025V ) = 60 kΩ 125µA ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.238 *Figure P15.237 - Bipolar Op-Amp VCC 1 0 DC 5 VEE 14 0 DC -5 V1 6 15 DC -74.17U AC 0.5 V2 7 15 DC 0 AC -0.5 VIC 15 0 DC 0 Q1 4 6 8 NBJT 1 Q2 5 7 8 NBJT 1 Q3 4 4 2 PBJT 1 Q4 5 4 3 PBJT 1 Q5 2 3 1 PBJT 1 Q6 3 3 1 PBJT 1 Q7 14 5 10 PBJT 1 Q8 11 10 1 PBJT 4 Q9 1 11 12 NBJT 1 Q10 14 13 12 PBJT 1 Q12 9 9 14 NBJT 1 Q14 8 9 14 NBJT 1 Q16 13 9 14 NBJT 7.78 IB 0 9 250U RBB 11 13 574 .MODEL NBJT NPN BF=150 VA=60 IS=15F .MODEL PBJT PNP BF=60 VA=60 IS=15F .OP .AC LIN 1 1000 1000 .PRINT AC VM(12) VP(12) .TF V(12) VIC .END SPICE Results: Vos = -74.17µV, Adm = 2.83 x 105, Acm = 0.507, CMRR = 115 dB, Rid = 81.6 kΩ, Rout = 523 Ω. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-141 15.239 (a) We require forward - active region operation of all transistors. For Q14 : VCB14 = 0 − VBE1 − (−VEE + VBE14 ) ≥ 0 → VEE ≥ 1.4V For Q1 : VCB1 = VCC − VEB 6 − VEB 4 ≥ 0 → VCC ≥ 1.4V For Q16 : VCB16 = 0 − VEB10 − (−VEE + VBE14 ) ≥ 0 → VEE ≥ 1.4V For Q 8 : VBC 8 = VCC − VEB 8 − VBE 6 ≥ 0 → VCC ≥ 1.4V So VCC ≥ 1.4V and VEE ≥ 1.4V (b) We require forward - active region operation of all transistors with VIC present. For Q14 : VCB14 = VIC − VBE1 − (−VEE + VBE14 ) = −1− 0.7 − (−VEE + 0.7) =≥ 0 → VEE ≥ 2.4V For Q1 : VCB1 = VCC − VEB 6 − VEB 4 − VIC = VCC − 0.7 − 0.7 −1 ≥ 0 → VCC ≥ 2.4V For an output range of ± 1V, For Q16 : VCB16 = VO − VEB10 − (−VEE + VBE14 ) = −1 ≥ 0 → VEE ≥ 1.4V For Q 8 : VBC 8 = VCC − VEB 8 − (VO + VBE 6 ) = VCC − 0.7 − (1+ 0.7) ≥ 0 → VCC ≥ 2.4V So VCC ≥ 2.4V and VEE ≥ 2.4V 15.240 (a) I C 22 = IC 20 = VCC − VEB22 − VBE20 − (−VEE ) 3V − 0.7 − 0.7 − (−3V ) = = 46.0µA R1 100kΩ IC23 = 3IC 22 = 138 µA | IC 24 = IC 22 = 46.0 µA | ⎛ 46.0µA ⎞ V ⎛ I ⎞ 0.025V ⎛ 46.0µA ⎞ ln⎜ I1 = T ln⎜ C 20 ⎟ = ⎟ = 6.25µAln⎜ ⎟ =→ I1 = 9.72µA 4kΩ R ⎝ I1 ⎠ ⎝ I1 ⎠ ⎝ I1 ⎠ (b) I 22V − 0.7 − 0.7 − (−22V ) = 426µA 100kΩ IC23 = 3IC 22 = 128 µA | IC 24 = IC 22 = 426 µA ⎛ 426µA ⎞ V ⎛I ⎞ I1 = T ln⎜ C 20 ⎟ = 6.25µAln⎜ ⎟ → I1 = 19.3µA R ⎝ I1 ⎠ ⎝ I1 ⎠ C 22 = IC20 = (c) The input bias current and input resistance of the amplifier are directly dependent upon I1 , whereas the gain of the interior amplifier stages is approximately independent of bias current. 15-142 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.241 250µA = 83.3 µA | I3 = IREF = 83.3 µA 3 V − VEB 22 − VBE 20 − (−VEE ) 12 − 0.7V − 0.7 − (−12) V IREF = CC | R1 = = 271 kΩ R1 83.3 µA V ⎛ I ⎞ 0.025V ⎛ 83.3µA ⎞ ln⎜ R2 = T ln⎜ REF ⎟ = ⎟ = 255 Ω I1 ⎝ I1 ⎠ 50µA ⎝ 50µA ⎠ I2 = 3IREF → IREF = 15.242 IREF = I3 = 300 µA | I2 = 3IREF = 900 µA VCC − VEB 22 − VBE 20 − (−VEE ) 15 − 0.7V − 0.7 − (−15) V | R1 = = 95.3 kΩ R1 300 µA V ⎛ I ⎞ 0.025V ⎛ 300µA ⎞ ln⎜ R2 = T ln⎜ REF ⎟ = ⎟ = 462 Ω I1 ⎝ I1 ⎠ 75µA ⎝ 75µA ⎠ IREF = 15.243 For forward - active region operation of Q3 , VBC 3 ≥ 0 VEE ≥ VIC + VBE1 + VBE 3 + VBE 7 + VBE 5 + VR1 For forward - active region operation of Q1, VCB1 ≥ 0 VCC − VEB 9 ≥ VIC For the output stage, VCC ≥ VBE15 + VI 3 = 0.7 + 0.7 = 1.4 V −VEB16 − VEB12 ≥ VBE11 + VR 5 − (−VEE ) → VEE ≥ 3VBE + VR1 ≅ 2.1V (a) VIC = 0, VEE ≥ 4VBE + VR 1 ≅ 2.8V | VCC − VEB 9 ≥ 0 → VCC ≥ 0.7V Combining these results yields : VCC ≥ 1.4V and VEE ≥ 2.8V (b) VIC = ±1, VEE ≥ 1+ 4VBE + VR 1 ≅ 3.8V | VCC − VEB 9 ≥ 1 → VCC ≥ 1.7V If also account for the output stage, VCC ≥ VO + VBE15 + VI 3 = 1 + 0.7 + 0.7 = 2.4 V Combining these results yields : VCC ≥ 2.4V and VEE ≥ 3.8V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-143 15.244 50µA (7.32µA) = 20.3µA 18µA 50µA Using Eq. 16.139 : io = −20(20.3µA)v id = (−0.406 mS )v id | IC 4 = (7.25µA) = 20.1µA 18µA ⎛ 20.3µA(1kΩ)⎞ 60V Rout 6 ≅ ro6⎜1+ = 2.84 MΩ ⎟ = 1.81ro6 | Rth = 1.81ro6 2ro4 = 0.952ro4 = 0.95 0.025V ⎠ 20.1µA ⎝ The input stage current is proportional to I1 : IC 2 = io = (−4.06 x 10 -4 )v id | Rth = 2.84 MΩ As a check, we know that g m ∝ IC and ro ∝ ⎛ 50µA ⎞ -4 io = 1.46x10−4 v id ⎜ ⎟ = −4.06 x 10 v id µ A 18 ⎝ ⎠ which underestimates Rth . 15.245 (a) R2 = β o2 ro2 2 = 1 . Using the results from Fig. 16.60, IC ⎛ 18µA ⎞ and Rth = 6.54 MΩ⎜ ⎟ = 2.35MΩ ⎝ 50µA ⎠ 50 60 + 15.7 = 2.84 MΩ | The cascode source uses up an extra VEB . 2 0.666mA (b) [y 22 ] = Rout11 R2 = 407kΩ 2.84 MΩ = 356kΩ (c ) Adm = 256(6.70mS)(356kΩ) = 6.11 x 10 5 −1 | The other y - parameters are unchanged. 15.246 +VCC A A 3A Q 23A Q 22A Q 24 I A 3 3A Q 22B Q 23B I R 2 1 I 1 Q Q 20 A 21 A R 2 -V EE 15-144 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.247 gm10 = 40(19.8µA) = 0.792mS | rπ 10 = 150(0.025V ) 60V = 189kΩ | ro10 = = 3.03MΩ 19.8µA 19.8µA 150(0.025V ) 60V = 5.63kΩ | ro11 = = 90.1kΩ 0.666mA 0.666mA *Problem 15.247 - Small Signal Parameters. V1 1 0 DC 0 V2 4 0 AC 1 RPI10 1 2 189K RO10 2 0 3.03MEG GM10 0 2 1 2 0.792M RE10 2 0 50K RPI11 2 3 5.63K RO11 4 3 90.1K GM11 4 3 2 3 26.6M RE11 3 0 100 R2 4 0 115K .TF I(V2) V1 .AC LIN 1 1000 1000 .PRINT AC IM(V2) IP(V2) IM(V1) IP(V1) .END gm11 = 40(0.666mA) = 26.6mS | rπ 11 = -1 Results : y11-1 = 2.38 MΩ | y12 = 3.27 x 10−10 S ≅ 0 | y 21 = 6.66 mS | y 22 = 81.9 kΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-145 15.248 IC11 = 50µA | IC 3 = IC 6 = IC 4 = 50µA 2 I IC1 = IC 3 = IC 7 = 50µA | IC 2 = IC 6 = IC 8 = 50µA | IC 9 = 2 C 8 (a) Assume large β F : IC11 = IREF = 100µA | IC 4 = IC 5 = βF VCE1 = VCE 2 = 15 − (−0.7) = 15.7V | VEC 4 = VEC 5 = 0.7V VCE 7 = VCE 8 = 0.7 + 0.7 = 1.4V | VCE 9 = 15 − (−15 + 0.7) = 29.3V | VCE10 = 0.7V VEC 3 = VEC 2 = (0 − 0.7) − (−15 + 1.4) = 12.9 | VCE11 = 0 − 0.7 − 0.7 − (−15) = 13.6V Q 1 2 3 IC (µA) 100 100 -50 VCE (V) 15.7 15.7 -12.9 4 5 6 7 8 9 10 11 -50 -0.7 -50 -0.7 -50 -12.9 50 1.4 50 1.4 --29.3 100 0.7 100 13.6 (b) Transistor Q11 replicates the reference current. This current divides in two and controls two matched current mirrors formed of Q4-Q3 and Q5-Q6. The currents of Q1 and Q7, and Q2 and Q8 are equal to the output current of Q3 and Q4. (c) v1 is the inverting input; v2 is the non-inverting input. g m5 = g m6 | g m2 = 2g m6 | ro8 = ro6 | io = g m6ve6 ve6 = v id Differential-mode Half Circuit Q2 v id 2 + - Q6 1 g m5 15-146 io 2 1 g m2 1 = v | io = g m6 vid ⎛ 1 1 ⎞ 2 id 2 1+ g m2 ⎜ ⎟ ⎝ g m5 g m6 ⎠ 1 1 1 Gm = g m6 = g m2 = (40)(100µA)= 1.00 mS 2 4 4 ⎡ ⎛ ⎞⎤ 1 6 = ro8 ro6⎢1+ g m6⎜ Rout = ro8 Rout ⎟⎥ ⎝ g m5 + g m2 ⎠⎦ ⎣ ⎛ 61.4V ⎞ ⎛ 72.9V ⎞ Rout = ro8 1.33r06 = ⎜ ⎟ 1.33⎜ ⎟ = 752 kΩ ⎝ 50µA ⎠ ⎝ 50µA ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15.249 (a) Assume large β F : IC 3 = IC 4 = β F IC 8 = IREF = 100µA | IC10 = IC 9 = IB 8 = IC 8 βF IC10 IC 8 I = = 50µAIC1 = IC 3 = IC 5 = 50µA | IC 2 = IC 4 = IC 6 = 50µA | IC 7 = 2 C 5 2 2 βF VCE1 = VCE 2 = 15 − (−0.7) = 15.7V | VCE 5 = VCE 6 = 0.7 + 0.7 = 1.4V VEC 3 = VEC 4 = 0 − 0.7 − (−15 + 1.4) = 12.9V | VCE 7 = 15 − (−15 + 0.7) = 29.3V VEC 8 = 0.7 + 0.7 = 1.4V | VCE 9 = 0.7V | VCE10 = 0 − 0.7 − 0.7 − (−15) = 13.6V Q 1 2 3 4 IC (µA) 50 50 -50 -50 VCE (V) 15.7 15.7 -12.9 -12.9 5 6 7 8 9 10 50 1.4 50 1.4 --29.3 -100 1.4 --0.7 --13.6 (b) Transistors Q9 and Q10 form a current mirror that replicates the base current of transistor Q8. The output current divides in two and forms the base currents of Q3 and Q4. Since Q3 and Q4 match Q8, the collector currents of Q1-Q6 will all be equal to IREF/2. (c) v1 is the inverting input; v2 is the non-inverting input. io = g m4ve4 | io = 2g m4ve4 2 g m2 v v 1 ve4 = id = vid | io = g m4 id ⎛ 1 ⎞ 4 2 2 1+ g m2⎜ ⎟ ⎝ g m4 ⎠ g m2 = g m4 | ro6 = ro4 | Q2 v id 2 Differential-mode Half Circuit io + - Q4 2 1 1 1 Gm = g m4 = g m2 = (40)(50µA)= 1.00 mS 2 2 2 ⎡ ⎛ 1 ⎞⎤ 4 = ro6 ro4 ⎢1+ g m4 ⎜ Rout = ro6 ROUT ⎟⎥ ⎝ g m2 ⎠⎦ ⎣ ⎛ 61.4V ⎞ ⎛ 72.9V ⎞ Rout = ro6 2ro4 = ⎜ ⎟ 2⎜ ⎟ = 864 kΩ ⎝ 50µA ⎠ ⎝ 50µA ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 15-147 CHAPTER 16 16.1 Av (s) = 50 s2 s2 | Amid = 50 | FL (s)= | Poles : - 2,-30 | Zeros : 0,0 (s + 2)(s + 30) (s + 2)(s + 30) Yes, s = −30 | Av (s) ≈ 50 s rad | ω L ≅ 30 s (s + 30) | fL = ω L 30 ≅ = 4.77 Hz 2π 2π 2 2 1 302 + 22 − 2(0) − 2(0) = 4.79 Hz 2π 50ω 2 | MATLAB : f L = −4.80 Hz Av (jω ) = ω 2 + 22 ω 2 + 302 fL = 16.2 Av (s) = 400s2 s2 s2 = 200 | A = 200 | F s = ( ) mid L 2s2 + 1400s + 100,000 (s + 619)(s + 80.8) (s + 619)(s + 80.8) Poles : - 619,-80.8 Av (s) ≈ 200 rad s | Zeros : 0, 0 | Yes, a 5 :1 split is sufficient | s = −619 s rad | ω L ≅ 619 s (s + 619) | fL ≅ 619 = 98.5 Hz 2π 2 2 1 80.82 + 6192 − 2(0) − 2(0) = 99.4 Hz 2π 200ω 2 | MATLAB : 100 Hz Av (jω ) = ω 2 + 80.82 ω 2 + 6192 fL ≅ 16.3 Av (s) = −150 s (s + 15) (s + 12)(s + 20) Poles : -12, - 20 fL ≅ | Amid = −150 | FL (s)= s(s + 15) (s + 12)(s + 20) rad rad | Zeros : 0, -15 | No, the poles and zeros are closely spaced. s s 2 2 1 122 + 202 − 2(0) − 2(15) = 1.54 Hz 2π Av (jω ) = 150ω ω 2 + 152 ω 2 + 122 ω 2 + 202 | MATLAB : f L = 2.72 Hz | ω L = 17.1 rad s Note that ωL =16.1 rad/s does not satisfy the assumption used to obtain Eq. (16.15), and the estimate using Eq. (16.15) is rather poor. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-1 16.4 ( )( )( ) 3x1011 10−4 10−5 9x1011 300 Av (s) = 2 = = 5 9 ⎛ s ⎞⎛ s ⎞ ⎛ s ⎞⎛ s ⎞ 3s + 3.3x10 s + 3x10 ⎜ 4 + 1⎟⎜ 5 + 1⎟ ⎜ 4 + 1⎟⎜ 5 + 1⎟ ⎝ 10 ⎠⎝10 ⎠ ⎝ 10 ⎠⎝10 ⎠ 1 Amid = 300 | FH (s)= ⎛ s ⎞⎛ s ⎞ ⎜ 4 + 1⎟⎜ 5 + 1⎟ ⎝ 10 ⎠⎝10 ⎠ 300 rad | ω H ≅ 10 4 s s +1 4 10 ⎞−1 ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎟ ⎜ 4 ⎟ + ⎜ 5 ⎟ − 2⎜ ⎟ − 2⎜ ⎟ ⎟ = 1.58 kHz ⎝ 10 ⎠ ⎝ 10 ⎠ ⎝ ∞⎠ ⎝ ∞⎠ ⎠ Poles : -10 4 ,-105 ⎛ 1 ⎜ fH ≅ 2π ⎜ ⎝ Av (jω ) = rad s | Yes : Av (s) ≈ 3x1011 ( ) ω + 10 2 16.5 4 2 ( ) ω + 10 2 ⎛ 5 2 | fH ≅ 10 4 = 1.59kHz 2π | MATLAB : f H = 1.58 kHz ⎞ ⎛ s ⎞ ⎜1+ ⎟ ⎝ 2x109 ⎠ Av (s) = = 300 ⎛ ⎛ s ⎞⎛ s ⎞ s ⎞ s ⎞⎛ 10 7 ⎜1+ 7 ⎟⎜1+ 9 ⎟ ⎜1+ 7 ⎟⎜1+ 9 ⎟ ⎝ 10 ⎠⎝ 10 ⎠ ⎝ 10 ⎠⎝ 10 ⎠ ⎛ s ⎞ ⎜1+ ⎟ ⎝ 3x109 ⎠ Amid = 300 | FH (s)= | Poles : -10 7 , -109 Zeros : - 3x109 , ∞ ⎛ ⎞ ⎛ ⎞ s s ⎜1+ 7 ⎟⎜1+ 9 ⎟ ⎝ 10 ⎠⎝ 10 ⎠ s ⎟ (3x10 )⎜⎝1+ 3x10 ⎠ 9 9 300 rad Yes : Av (s ) ≈ | ω H ≅ 10 7 ⎛ ⎞ s s ⎜1+ 7 ⎟ ⎝ 10 ⎠ 10 4 | fH ≅ = 1.59 MHz 2π −1 ⎛ 2 2 2 2⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞ 1 ⎜ 1 1 1 1 − 2⎜ ⎟ ⎟ = 1.59 MHz fH = ⎜ 7 ⎟ + ⎜ 9 ⎟ − 2⎜ 9⎟ ⎜ 2π ⎝ 10 ⎠ ⎝ 10 ⎠ ⎝ 3x10 ⎠ ⎝ ∞⎠ ⎟ ⎠ ⎝ Av (jω ) = 17-2 ( 2x109 ω 2 + 3x109 ( ) ω + 10 2 7 2 ) 2 ( ) ω + 10 2 9 2 | MATLAB : f H = 1.59 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.6 ⎛ ⎛ s ⎞ s ⎞ 2x109 5x105 ⎜1+ 1+ ⎟ ⎜ ⎟ ⎝ 5x105 ⎠ ⎝ 5x105 ⎠ Av (s) = = 3333 ⎛ ⎛ s ⎞⎛ s ⎞ s ⎞ s ⎞⎛ 5 6 1.5x10 2x10 ⎜1+ 1+ 1+ 1+ ⎟ ⎜ ⎟ ⎜ ⎟ ⎜ ⎟ ⎝ 1.3x105 ⎠⎝ 2x106 ⎠ ⎝ 1.5x105 ⎠⎝ 2x106 ⎠ ⎛ s ⎞ ⎜1+ ⎟ rad ⎝ 5x105 ⎠ Amid = 3333 | FH (s)= | Poles : -1.5x105 , - 2x106 ⎛ s s ⎞⎛ s ⎞ 1+ ⎜1+ ⎟ ⎜ ⎟ ⎝ 1.5x105 ⎠⎝ 2x106 ⎠ rad Zeros : - 5x105 , ∞ | No, the poles and zeros are closely spaced and will interact. s −1 ⎛ 2 2 2 2⎞ ⎛ 1 ⎞ ⎛1⎞ 1 ⎜ ⎛ 1 ⎞ ⎛ 1 ⎞ fH ≅ +⎜ − 2⎜ − 2⎜ ⎟ ⎟ = 26.3 kHz ⎜ ⎟ ⎟ ⎟ 5 6 5 2π ⎜ ⎝ 1.5x10 ⎠ ⎝ 2x10 ⎠ ⎝ 5x10 ⎠ ⎝ ∞⎠ ⎟ ⎠ ⎝ ( ( )( )( ) ) ( ) + (2x10 ) 2x109 ω 2 + 5x105 Av (jω ) = ( ω + 1.3x10 2 5 ) 2 ω 2 2 6 2 | MATLAB : 26.3 kHz 16.7 6x108 s2 1 s ⎞ s ⎞⎛ 1000(2000) (s + 1)(s + 2) ⎛ ⎜1+ ⎟⎜1+ ⎟ ⎝ 1000 ⎠⎝ 2000 ⎠ ⎤ ⎡ ⎥ ⎢ ⎡ ⎤ s2 1 ⎥ = 200F (s)F (s) ⎢ ⎥ Av (s) = 300 ⎢ L H ⎛ ⎞ ⎛ ⎞ ⎢ s s + 1 s + 2 s ⎢⎣ ( )( )⎥⎦ ⎢⎜1+ ⎟⎜1+ ⎟⎥⎥ ⎣⎝ 500 ⎠⎝ 1000 ⎠⎦ Av (s) = rad | Zeros : 0, 0, ∞, ∞ | No. | No. s 6x108 ω 2 Poles; -1, - 2, -1000, - 2000 Av (jω ) = fL = 1 2π 12 + ω 2 22 + ω 2 10002 + ω 2 20002 + ω 2 1 + (2) − 2(0) − 2(0) () 1 fH = 2π 03/09/2007 2 2 2 2 = 0.356 Hz | MATLAB : 0.380 Hz ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎛ 1 ⎞2 ⎜ ⎟ +⎜ ⎟ − 2⎜ ⎟ − 2⎜ ⎟ = 142 Hz | MATLAB : 133 Hz ⎝1000 ⎠ ⎝ 2000 ⎠ ⎝ ∞⎠ ⎝ ∞⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-3 16.8 ⎛ s ⎞ 1+ ⎜ ⎟ s (s + 1) 10 (200) ⎝ 200 ⎠ Av (s) = 2 2 (100) (300) (s + 3)(s + 5)(s + 7)⎛⎜1+ s ⎞⎟ ⎛⎜1+ s ⎞⎟ ⎝ 100 ⎠ ⎝ 300 ⎠ ⎤ ⎡ ⎛ s ⎞ ⎥ ⎢ ⎜1+ ⎟ ⎤ ⎡ s2 (s + 1) 200 ⎠ ⎥ ⎢ ⎝ 5 ⎥ = 6.67x105 FL (s )FH (s) Av (s) = 6.67x10 ⎢ 2 ⎥ ⎢ ⎞⎛ ⎞ ⎢⎣(s + 3)(s + 5)(s + 7)⎥⎦ ⎛ ⎢⎜1+ s ⎟ ⎜1+ s ⎟ ⎥ ⎢⎣⎝ 100 ⎠ ⎝ 300 ⎠ ⎥⎦ 10 2 No dominant pole at either low or high frequencies. Av (jω ) = fL = 1 2π 1010 ω 2 ω 2 + 12 ω 2 + 2002 ( ) ω 2 + 32 ω 2 + 52 ω 2 + 72 ω 2 + 1002 ω 2 + 3002 1 − 2(0) (3) + (5) + (7) − 2() 2 2 2 2 2 = 1.43 Hz | MATLAB : 1.62 Hz −1 ⎛ 2 2 2 2 2⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞ ⎛ ⎞ 1 ⎜ 1 1 1 1 1 +⎜ +⎜ − 2⎜ − 2⎜ ⎟ ⎟ = 12.5 Hz | MATLAB : 10.6 Hz fH = ⎜ ⎟ ⎟ ⎟ ⎟ 2π ⎜ ⎝ 100 ⎠ ⎝ 100 ⎠ ⎝ 300 ⎠ ⎝ 200 ⎠ ⎝ ∞⎠ ⎟ ⎠ ⎝ 17-4 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.9 Low frequency: 0.1 µF 2kΩ 0.1 µF Rout v 2.43 M Ω Rin 43 k Ω i 1 MΩ 10 µF 13 k Ω Mid-band: 2kΩ Rout v 43 k Ω Rin i 1 MΩ 2.43 M Ω (b) Avt = ( vd = −g m RL = −g m Rout R3 vg )| Amid = 2(0.2mA) Rin 2I D Avt | g m = = = 0.400mS RI + Rin VGS − VTN 1V Rin = 2.43MΩ | Rout = RD ro ≅ RD = 43kΩ assuming λ = 0 since it is not specified. ⎛ 2.43MΩ ⎞ Amid = −⎜ ⎟(0.400mS ) 43kΩ 1MΩ = −16.5 ⎝ 2kΩ + 2.43MΩ ⎠ 1 rad 1 rad ω1 = −7 = 4.11 | ω2 = = 9.59 −7 s s 10 F (2.43MΩ + 2kΩ) 10 F (43kΩ + 1MΩ) ( ( ω3 = ) ) ( ) 1 1 rad = = 47.7 −5 ⎛ ⎞ s 10 F 13kΩ 2.5kΩ 1 10−5 F ⎜13kΩ ⎟ gm ⎠ ⎝ ( ( ) ω3 is dominant : f L ≅ )( ) | ωZ = 1 (10 F )(13kΩ) −5 = 7.69 rad s ω3 = 7.59 Hz 2π 2 2 2 2 1 4.11) + (9.59) + (47.7) − 2(7.69) = 7.58 Hz ( 2π = 0.2mA(56kΩ)+ 5V = 16.2 V Using Eq. (16.15) yields : f L ≅ (c) VDD = I D (RD + RS )+ VDS 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-5 16.10 0.1 µF 5kΩ 0.1 µF Rout v Rin 220 k Ω 43 k Ω i 430 k Ω 560 k Ω 10 µF 13 k Ω Low frequency: 5k Ω Rout 220 k Ω 43 k Ω Rin vi 243 k Ω Mid-band: Avt = ( vd = −g m RL = −g m Rout R3 vg )| Amid = 2(0.2mA) Rin 2I D Avt | g m = = = 0.400mS RI + Rin VGS − VTN 1V Rin = 243kΩ | Rout = RD ro ≅ RD = 43kΩ assuming λ = 0 since it is not specified. ⎛ 243kΩ ⎞ Amid = −⎜ ⎟(0.400mS ) 43kΩ 220kΩ = −14.1 ⎝ 5kΩ + 243kΩ ⎠ ( ω1 = ω3 = 1 (10 F )(243kΩ + 5kΩ) −7 rad s | ω2 = 1 (10 F )(43kΩ + 220kΩ) −7 1 1 rad = = 47.7 −5 ⎛ ⎞ s 10 F 13kΩ 2.5kΩ 1 10−5 F ⎜13kΩ ⎟ gm ⎠ ⎝ ( ( ) Using Eq. (17.16) : f L ≅ 17-6 = 40.3 ) 1 2π )( ) | ωZ = (40.3) + (38.0) + (47.7) − 2(7.69) 2 2 2 2 = 38.0 1 rad s (10 F )(13kΩ) −5 = 11.5 Hz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 = 7.69 rad s 16.11 (a ) Assume that ω C3 = is dominant : f L ≅ ω3 = 2π (50) = 314 ( 3 ) = 1.5 µF | ω3 = 1 (10 F )(2.43MΩ + 2kΩ) −7 (c) Assume that ω ⎛ 1 ω3⎜ RS ⎝ 1⎞ ⎟ gm ⎠ = 3 1 = 4.11 rad s | ω2 = ( 2 ) 1 (10 F )(43kΩ + 1MΩ) −7 2 2 ( 1 ) 1 2π rad s | ω2 = = 318 2 = 49.3 Hz rad 1 rad | ωZ = = 51.3 s s (1.5µF )(13kΩ) 1 (10 F )(43kΩ + 220kΩ) −7 2 rad s 2I D 0.4mA = = 0.4mS 1V VGS − VTN (40.3) + (38.0) + (318) − 2(51.3) 2 = 9.59 rad s = 1.52 µF where g m = 1.5 µF 13kΩ 2.5kΩ = 40.3 rad 1 rad | ωZ = = 51.3 s s (1.5µF )(13kΩ) (4.11) + (9.59) + (318) − 2(51.3) 314 13kΩ 2.5kΩ Using Eq. (16.15) yields : f L ≅ 03/09/2007 1 2π 1 (10 F )(243kΩ + 5kΩ) −7 ) = 318 is dominant : f L ≅ ω3 = 2π (50)= 314 Choose C3 = 1.5 µF | ω3 = ω1 = ( 1 1.5 µF 13kΩ 2.5kΩ Using Eq. (17.16) yields : f L ≅ C3 = rad s 1 1 2I D 0.4mA = = 1.52 µF where g m = = = 0.4mS ⎛ ⎞ VGS − VTN 1V 314 13kΩ 2.5kΩ 1 ω3⎜ RS ⎟ gm ⎠ ⎝ (b) Choose C ω1 = 3 2 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 = 38.0 rad s = 50.1 Hz 17-7 16.12 4.7 µF C1 RI C2 1 µF 100 Ω Rin vi Rout RD 1.3 k Ω R 100 k Ω 4.3 k Ω S R3 Low Frequency: (b) Av (s) = Amid (c )Amid s2 | ω1 = (s + ω1)(s + ω 2 ) 1 1 | 2 zeros at ω = 0 ⎛ C2 (RD + R3 ) 1⎞ C1⎜ RI + RS ⎟ gm ⎠ ⎝ ⎛ Rin ⎞ ⎛ Rin ⎞ ⎛ Rin ⎞ =⎜ ⎟ Avt = ⎜ ⎟ gm RL = ⎜ ⎟ gm (Rout R3 ) | gm = 5mS ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ Rin = RS | ω2 = 1 = 173Ω | RL = Rout R3 | Rout = RD ro = RD = 4.3kΩ (assuming ro = ∞) gm ⎛ ⎞ 173Ω Amid = ⎜ ⎟(0.005)(4.3kΩ 100kΩ) = +13.1 → 22.3 dB ⎝ 100Ω + 173Ω ⎠ 1 rad 1 rad ω1 = = 779 | ω 2 = −6 = 9.59 −6 4.7x10 (100 + 173) s 10 (4.3kΩ + 100kΩ) s ω1 is dominant : f L ≅ ω1 = 124 Hz 2π 16.13 (a) Assume ω1 Rin = RS 17-8 rad 1 | C1 = ω1 (RI + Rin ) s 1 1 = 1300Ω 200Ω = 173Ω | C1 = = 0.583 µF 3 gm 6.28x10 (100 + 173) (b) Choose ω2 = is dominant : ω L ≅ ω1 = 2π (1000Hz) = 6280 C1 = 0.56 µF | ω1 = 1 rad = 6540 0.56x10 (100 + 173) s −6 ω 1 rad = 10.3 | ω1 is dominant : f L ≅ 1 = 1040 Hz 2π 10 (22kΩ + 75kΩ) s −6 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.14 4.7 µF 200 Ω v 1 µF Rin Rout 4.3 k Ω i 2.2 k Ω 51 k Ω Low frequency: 200 Ω Rin vi Rout 4300 Ω 2.2 k Ω 51 k Ω Mid-band: s2 | ω = mid (s + ω1)(s + ω2 ) 1 1 (b) A (s)= A v (c) A mid 1 | ω2 = | 2 zeros at ω = 0 ⎛ C2 (RC + R3 ) 1⎞ C1⎜ RS + RE ⎟ gm ⎠ ⎝ ⎛ Rin ⎞ ⎛ Rin ⎞ ⎛ Rin ⎞ =⎜ ⎟ Avt = ⎜ ⎟ g m RL = ⎜ ⎟ g m Rout R3 | g m = 40(1mA)= 0.04S ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ ⎝ RI + Rin ⎠ ( ) 1 = 24.9Ω | RL = Rout R3 | Rout = RC ro = RC = 2.2kΩ gm ⎛ ⎞ 24.9Ω Amid = ⎜ ⎟(0.04) 2.2kΩ 51kΩ = +9.34 →19.4 dB ⎝ 200Ω + 24.9Ω ⎠ 1 rad 1 rad ω1 = = 946 | ω2 = −6 = 18.8 −6 s s 4.7x10 (200 + 24.9) 10 (2.2kΩ + 51kΩ) Rin = RE ( ω1 is dominant : f L ≅ (d) g m ) ω1 = 151 Hz 2π = 40(10µA)= 0.0004S | Rin = 2.49kΩ | Rout = RC ro = RC = 220kΩ ⎛ ⎞ 2.49kΩ Amid = ⎜ ⎟(0.0004) 220kΩ 510kΩ = +56.9 → 35.1 dB ⎝ 200Ω + 2.49kΩ ⎠ 1 rad 1 rad ω1 = = 79.1 | ω2 = −6 = 1.37 −6 s s 4.7x10 (200 + 2.49kΩ) 10 (220kΩ + 510kΩ) ( ω1 is dominant : f L ≅ 03/09/2007 ) ω1 = 12.6 Hz 2π ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-9 16.15 (a ) Assume ω 1 is dominant : ω L ≅ ω1 = 2π (500Hz)= 3140 rad s C1 = 1 1 | Rin = RE | g m = 40(1mA) = 0.04S | Rin = 4300Ω 25Ω = 24.9Ω gm ω1(RI + Rin ) C1 = 1 = 1.42 µF 3.14x10 (200 + 24.9) 3 (b) Choose ω2 = C1 = 1.5 µF | ω1 = 1 rad = 2960 s 1.5x10 (200 + 24.9) 1 rad = 18.8 s 10 (2.2kΩ + 51kΩ) −6 (c) Assume ω 1 −6 | ω1 is dominant : f L ≅ is dominant : ω L ≅ ω1 = 2π (500Hz)= 3140 ω1 = 472 Hz 2π rad s C1 = 1 1 | Rin = RE | g m = 40(10µA) = 0.0004S | Rin = 430kΩ 2500Ω = 2.49kΩ gm ω1(RI + Rin ) C1 = 1 = 0.118 µF | Choose C1 = 0.12 µF 3.14x10 (200 + 2490) ω1 = 1 rad = 2100 s 0.12x10 (200 + 2490) 3 −6 ω1 is dominant : f L ≅ 17-10 | ω2 = 1 rad = 18.8 s 10 (2.2kΩ + 51kΩ) −6 ω1 = 493 Hz 2π ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.16 (a) gm = 40IC = 40(0.175mA) = 7.00mS | rπ = βo gm = 100 = 14.3kΩ | ro = ∞ (VA not given) 7.00mS Rin = R1 R2 rπ = 100kΩ 300kΩ 14.3kΩ = 12.0kΩ | RL = RC R3 = 43kΩ 100kΩ = 30.1kΩ Amid = Rin 12.0kΩ gm RL = (7.00mS)(30.1kΩ) = −194 RI + Rin 1kΩ + 12.0kΩ SCTC : R1S = RI + Rin = 1kΩ + 12.0kΩ = 13.0kΩ | Rth = R1 R2 RI = 100kΩ 300kΩ 1kΩ = 987Ω R2S = RE fL ≅ Rth + rπ 987Ω + 14.3kΩ = 15kΩ = 150Ω | R3S = RC + R3 = 43kΩ + 100kΩ = 143kΩ βo + 1 101 ⎤ (38.5 + 667 + 69.9) 1 1 ⎡ 1 1 + + = 123 Hz ⎢ ⎥= 2π 2π ⎣2x10−6 (13.0kΩ) 10x10−6 (150Ω) 1x10−7 (143kΩ)⎦ (b) Note that the Q-point assumed in part (a) is not quite correct. SPICE yields: (144 µA, 3.67 V), Amid = 43.9 dB, fL = 91 Hz (c ) VEQ = VCC IC = β F R1 100kΩ = 12 = 3V | REQ = R1 R2 = 100kΩ 300kΩ = 75.0kΩ R1 + R2 100kΩ + 300kΩ VEQ − VBE REQ + (β F + 1)RE = 100 3 − 0.7 = 145µA 75kΩ + (101)15kΩ VCE = VCC − IC RC − IE RE = 12 − (0.145mA)(43kΩ) − 101 (0.145mA)(15kΩ) = 3.57 V 100 These values agree with the SPICE results listed above in part (b). 16.17 (a ) Use the values from Section 16.3.1, and assume ω3 is dominant. ω L = 2π (2500Hz)= 15700 C3 = rad s | ω3 = ω L − ω1 − ω2 = 15700 − 225 + 96.1 = 15390 rad s 1 1 = = 2.86 µF ω3 R3S 15390(22.7Ω) (b) Choose C3 = 2.7 µF | ω3 = 1 2.7x10 −6 (22.7Ω) = 16320 rad s rad rad 225 + 96.1+ 16320 | ω1 = 225 | fL ≅ = 2650 Hz s s 2π or if ω L must be no more than 2500 Hz, choose C3 = 3.3 µF ω2 = 96.1 ω3 = 1 3.3x10 03/09/2007 −6 (22.7Ω) = 13350 rad s | fL ≅ 225 + 96.1+ 13350 = 2180 Hz 2π ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-11 16.18 1k Ω 43 k Ω 43 k Ω Rin v i 100k Ω 300k Ω 75 k Ω 21.5 k Ω (a) Mid-band: 1k Ω 1 µF 5 µF 43 k Ω vi 43 k Ω 75 k Ω 13 k Ω 22 µF Low frequency: (b) g m = 40IC = 40(0.164mA)= 6.56mS | rπ = βo gm = 100 = 15.2kΩ | ro = ∞ (VA not given) 6.56mS Rin = R1 R2 rπ = 100kΩ 300kΩ 15.2kΩ = 12.6kΩ | RL = RC R3 = 43kΩ 43kΩ = 21.5kΩ Amid = Rin 12.6kΩ g m RL = (6.56mS )(21.5kΩ)= −131 RI + Rin 1kΩ + 12.6kΩ SCTC : R1S = RI + Rin = 1kΩ + 12.6kΩ = 13.6kΩ | Rth = R1 R2 RI = 100kΩ 300kΩ 1kΩ = 987Ω Rth + rπ 987Ω + 15.2kΩ = 13kΩ = 158Ω | R3S = RC + R3 = 43kΩ + 43kΩ = 86kΩ βo + 1 101 ⎤ (14.7 + 288 + 11.6) 1 1 ⎡ 1 1 ⎢ ⎥= fL ≅ + + = 50.0 Hz 2π 2π ⎢⎣5x10−6 (13.6kΩ) 22x10−6 (158Ω) 1x10−6 (86kΩ)⎥⎦ ⎛ 101 ⎞ (c) VCC = I E RE + VEC + IC RC = 0.164mA⎜⎝100 ⎟⎠(13kΩ)+ 2.79V + 0.164mA(43kΩ)= 12.0 V R2S = RE 17-12 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.19 SCTC : R1S = RI + RG = 1kΩ + 1MΩ = 1.00 MΩ | ω1 = R2S = RS 1 1 1 rad = 6.8kΩ = 607Ω | ω2 = = 165 gm 1.5mS s 607Ω(10µF ) R3S = RD + R3 = 22kΩ + 68kΩ = 90kΩ | ω3 = fL ≅ 1 rad = 10.0 s 1.00 MΩ(0.1µF ) (10.0 + 165 + 111) = 45.5 Hz 1 rad = 111 s 90kΩ(0.1µF ) 2π 16.20 SCTC : R1S = RI + RG = 1kΩ + 500kΩ = 501kΩ | ω1 = R2S = RS 1 1 1 rad = 10kΩ = 1.18kΩ | ω2 = = 84.8 gm 0.75mS s 1.18kΩ(10µF ) R3S = RD + R3 = 43kΩ + 10kΩ = 53kΩ | ω3 = fL ≅ 1 rad = 20.0 s 501kΩ(0.1µF ) (20.0 + 84.8 + 189) = 46.8 Hz 03/09/2007 1 rad = 189 s 53kΩ(0.1µF ) 2π ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-13 16.21 C1 R I 2k Ω v C 4.7 µF R 3 12 k Ω i C R4 892 k Ω 2 3 1 µF R7 22 k Ω 100 k Ω 0.1 µF (a) Low Frequency: 2kΩ vi Rin 12 k Ω 22 k Ω 100 k Ω Mid-band: 2(0.1mA) 1 = 0.200mS | = 5000Ω 1V gm 1 Rin = RS = 12kΩ 5kΩ = 3.53kΩ | RL = 22kΩ 100kΩ = 18.0kΩ gm Rin 3.53kΩ Amid = gm RL = (0.200mS)(18kΩ) = 2.30 (7.24dB) RI + Rin 2kΩ + 3.53kΩ 1 1 rad ω1 = = = 38.5 | ω 2 = doesn't matter since ig = 0! −6 C1(RI + Rin ) 4.7x10 (2kΩ + 3.53kΩ) s gm = ω3 = 1 1 rad 1 = −7 = 82.0 | fL ≅ (38.5 + 82.0) = 19.2Hz C3 (R3 + R7 ) 10 (100kΩ + 22kΩ) s 2π 17-14 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.22 2kΩ 2kΩ 4.7 µF 10 µF vi Rin v 75 k Ω 13 k Ω in 11.5 k Ω 100 k Ω (a) Low frequency (b) R 75 k Ω i Mid-band = R1 R2 rπ + (β o + 1)RL | RL = 13kΩ 100kΩ = 11.5kΩ | rπ = [ ] [ 100 = 10.0kΩ 40(0.25mA) ] Rin = R1 R2 rπ + (β o + 1)RL = 100kΩ 300kΩ 10.0kΩ + (101)11.5kΩ = 70.5kΩ Amid = 101(11.5kΩ) Rin (β o + 1)RL = 0.972 = 0.963 | RB = R1 R2 = 75kΩ RI + Rin Rin 2 + 10.0 + 101(11.5) kΩ [ [ ] [ ] ] R1S = RI + RB rπ + (β o + 1)RL = 2kΩ + 75kΩ 10.0kΩ + (101)11.5kΩ = 72.5kΩ ω1 = 1 rad = 2.94 −6 s (72.5kΩ)4.7x10 R3S = R7 + RE ω3 = 1 ( ) 10−5 105 03/09/2007 RB RI + rπ (β =1 o + 1) rad s = 100kΩ + 13kΩ fL ≅ 1.95kΩ + 10.0kΩ = 100kΩ 101 (2.94 + 1) = 0.627Hz 2π ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-15 16.23 2k Ω 4.7 µF v 892 k Ω 0.1 µF i 100 k Ω 12 k Ω (a) Low Frequency: 2k Ω Rin v i 892 k Ω 10.7 k Ω Mid-band: (b) g m Amid = = 2(0.1mA) 0.75V = 0.267mS | Rin = R1 R2 = 892kΩ | RL = 12kΩ 100kΩ = 10.7kΩ (0.267mS )(10.7kΩ) = +0.739 Rin g m RL = 0.998 RI + Rin 1+ g m RL 1+ (0.267mS )(10.7kΩ) (-2.62 dB) ω1 = 1 1 rad = = 0.238 −6 s C1(RI + Rin ) 4.7x10 (2kΩ + 892kΩ) ω3 = 1 1 rad = = 97.2 ⎤ ⎡ ⎤ ⎡ ⎛ ⎛ ⎞ s 1 1⎞ −7 C3⎢ R7 + ⎜ RS ⎟⎥ 10 ⎢100kΩ + ⎜12kΩ ⎟⎥ 0.267mS ⎠⎥⎦ g m ⎠⎥⎦ ⎢⎣ ⎢⎣ ⎝ ⎝ 1 (0.238 + 97.2)= 15.5 Hz 2π (c) VDD = VDS + I S RS = 8.8V + 0.1mA(12kΩ)= 12.0 V fL ≅ 17-16 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.24 3 1 rad = 2π (500) = 3140 s i=1 RisC i SCTC requires : ω L ≅ ∑ ω1 = 1 rad = 4.11 s (10 F )(2.43MΩ + 1kΩ) −7 | ω2 = 1 rad = 9.59 s (10 F )(43kΩ + 1MΩ) −7 ω1 + ω 2 << ω L | ω 3 will be dominant → ω 3 ≅ ω L ω3 = 1 | gm = 2(0.2mA) 2ID 1 = = 0.400mS | = 2.50kΩ VGS − VTN 1V gm ⎛ 1⎞ C3⎜ RS ⎟ gm ⎠ ⎝ 1 C3 = = 0.152 µF → 0.15 µF from Appendix C 3140(13kΩ 2.5kΩ) 16.25 3 SCTC requires : ω L ≅ ∑ i=1 ω2 = 1 C2 (RC + R3 ) = 1 rad = 2π (100) = 628 RisCi s 1 (10 F )(2.2kΩ + 51kΩ) −6 = 18.8 rad << ω L | ω1 will be dominant → ω L ≅ ω1 s 1 1 1 | = = 25Ω ⎞ ⎛ g m 40 10−3 1 C1⎜ RI + RE ⎟ gm ⎠ ⎝ 1 C1 = = 7.08 µF → 6.8 µF nearest value in Appendix C 628 200Ω + 4.3kΩ 25Ω ω1 = ( ) ( ) Note : We might want to choose 8.2 µF to insure that f L ≤ 100 Hz. 3 1 (b) SCTC requires : ω ≅ ∑ R C L i=1 ω2 = 1 is (10 F )(220kΩ + 510kΩ) −6 = 2π (100) = 628 i = 1.37 rad s rad s | ω1 will be dominant → ω L ≅ ω1 1 1 1 | = = 2.5kΩ ⎞ ⎛ g m 40 10−5 1 C1⎜ RI + RE ⎟ gm ⎠ ⎝ 1 C1 = = 0.592 µF → 0.56 µF nearest value in Appendix C 628 200Ω + 430kΩ 2.5kΩ ω1 = ( ) ( ) Note : We might want to use 0.68 µF to insure that f L ≤ 100 Hz. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-17 16.26 gm = 40IC = 40(0.164mA) = 6.56mS | rπ = SCTC requires : 3 1 i=1 is ∑R C = 2π (20) = 126 i βo gm = 100 = 15.2kΩ | ro = ∞ (VA not given) 6.56mS rad s R1S = RI + (RB rπ ) = 1kΩ + (75kΩ 15.2kΩ) = 13.6kΩ | ω1 = R3S = RC + R3 = 43kΩ + 43kΩ = 86kΩ | ω 3 = ω 2 = 126 −14.7 −11.6 = 99.7 C2 ≅ 1 = 14.7 5x10 (13.6kΩ) −6 1 = 11.6 1x10 (86kΩ) −6 (RB RI )+ rπ = 13kΩ 987Ω + 15.2kΩ = 158Ω rad | R2S = RE βo + 1 s 101 1 = 63.5 µF → 68 µF from Appendix C 99.7(158) 16.27 SCTC requires : 3 1 i=1 is ∑R C = 2π (1) = 6.28 i rad s However, R3S = R3 + R7 = 22kΩ + 100kΩ = 122kΩ 1 rad rad ω3 = = 82.0 > 6.28 | The design goal cannot be met. −7 1x10 (122kΩ) s s It is not possible to force f L below the limit set by C3 . 16.28 3 1 rad = 2π (10) = 62.8 | RG = R1 R2 = 892kΩ R s C is i i=1 SCTC requires : ω L ≅ ∑ ω1 = 1 1 rad = = 0.238 | ω L >> ω1 → ω 3 is dominant −6 C1(RI + RG ) 4.7x10 (2kΩ + 892kΩ) s 1 1 0.75V | = = 3.75kΩ ⎡ ⎛ gm 2(0.1mA) 1 ⎞⎤ C3⎢R7 + ⎜ RS ⎟⎥ ⎢⎣ ⎝ gm ⎠⎥⎦ 1 rad = 0.155 → 0.15 µF using Appendix C C3 = s 62.8 100kΩ + (12kΩ 3.75kΩ) ωL ≅ ω3 = [ 17-18 ] ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.29 3 SCTC requires : ω L ≅ ∑ i=1 1 rad = 2π (5) = 31.4 RisCi s RL = 13kΩ 100kΩ = 11.5kΩ | rπ = [ ] 100 = 10.0kΩ 40(0.25mA) [ ] R1S = RI + RB rπ + (β o + 1)RL = 2kΩ + 75kΩ 10.0kΩ + (101)11.5kΩ = 72.5kΩ ω1 = 1 rad = 2.94 −6 s (72.5kΩ)4.7x10 R3S = R7 + RE C3 = (R B ) RI + rπ (β o + 1) | ω3 = 31.4 − 2.94 = 28.5 = 100kΩ + 13kΩ rad s 1.95kΩ + 10.0kΩ = 100kΩ 101 1 = 0.351 µF → 0.39 µF using the values from Appendix C. 28.5(100kΩ) 16.30 fT = 1 ⎛ gm ⎞ g ⎜⎜ ⎟⎟ | Cπ = m − Cµ | gm = 40IC 2π ⎝ C π + C µ ⎠ 2πf T IC fT Cπ Cµ 1/2πrxCµ 10 µA 50 MHz 0.773 pF 0.5 pF 1.59 GHz 100 µA 300 MHz 0.75 pF 1.37 pF 580 MHz 50 µA 1 GHz 2.93 pF 0.25 pF 3.19 GHz 10 mA 6.06 GHz 10 pF 0.500 pF 1.59 GHz 1 µA 3.18 MHz 1 pF 1 pF 795 MHz 1.18 mA 5 GHz 1 pF 0.5 pF 1.59 GHz 16.31 Cπ = gm τ F | Cπ = gm ωT − Cµ | VCB = 5 − 0.7 = 4.3V | Cµ = Cµo 1+ VCB = φ jc 2 pF = 0.832 pF 4.3V 1+ 0.9V 40(2x10−3 ) Cπ 24.6x10−12 Cπ = − 0.832 pF = 24.6 pF | τ F = = = 0.308ns = 308 ps gm 40(2x10−3 ) 2π (5x10 8 ) 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-19 16.32 ⎞ gm 1 ⎛ ⎜ ⎟ | gm = 2K n ID 2π ⎝ CGS + CGD ⎠ fT = ID fT CGS CGD 10 µA 15.9 MHz 1.5 pF 0.5 pF 250 µA 79.6 MHz 1.5 pF 0.5 pF 2.47 mA 250 MHz 1.5 pF 0.5 pF 16.33 (a) fT = 3 µn (VGS − VTN ) 3 600(0.25V ) cm 2 = = 22.5 GHz 2 2 10−4 2 V − s L2 (b) fT = 3 µn (VGS − VTN ) 3 250(0.25V ) cm 2 = = 9.38 GHz 2 2 10−4 2 V − s L2 ( ) ( ) (c) NMOS : f T 3 µn (VGS − VTN ) 3 600(0.25V ) cm2 = = 2.25 THz 2 2 10−5 2 V − s L2 = PMOS : f T = ( ) 3 µn (VGS − VTN ) 3 250(0.25V ) cm2 = = 938 GHz 2 2 10−5 2 V − s L2 ( ) (d ) NMOS : fT = PMOS : f T = 16.34 (a) r π = 3 µn (VGS − VTN ) 3 600(0.25V ) cm2 = = 36.0 THz 2 2 2.5x10−6 2 V − s L2 ) ( ) 3 µn (VGS − VTN ) 3 250(0.25V ) cm2 = = 15.0 GHz 2 2 2.5x10−6 2 V − s L2 125(0.025V ) 1mA ( = 3.13kΩ | Rin = 7.5kΩ (rx + rπ ) = 2.44kΩ | RL = 4.3kΩ 100kΩ = 4.12kΩ ⎛ 2.44kΩ ⎞ Rin g m RL = −⎜ ⎟(40mS )(4.12kΩ)= −117 RI + Rin ⎝1kΩ + 2.44kΩ ⎠ ⎛ 2.21kΩ ⎞ (b) Rin = 7.5kΩ rπ = 2.21kΩ | Amid = −⎜⎝1kΩ + 2.21kΩ ⎟⎠(40mS )(4.12kΩ)= −113 ( ) g m = 40 10−3 = 40mS | Amid = − 17-20 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.35 125(0.025V ) rπ = = 3.13kΩ | g m = 40(1mA) = 40mS | RL = 3kΩ 47kΩ = 2.82kΩ 1mA Rin = RB rx + rπ + (β o + 1)RL = 100kΩ 0.35kΩ + 3.13kΩ + (126)2.82kΩ = 78.2kΩ [ (a) A mid (b) R in Amid ] = Amid [ [ ] ⎤ ⎤ β o + 1)RL 126(2820) ( 78.2kΩ ⎡ Rin ⎡ ⎥ ⎥ = 0.978 ⎢ ⎢ = = RI + Rin ⎢⎣ rx + rπ + (β o + 1)RL ⎥⎦ 1kΩ + 78.2kΩ ⎢⎣350 + 3130 + 126(2820)⎥⎦ ] [ ] = RB rπ + (β o + 1)RL = 100kΩ 3.13kΩ + (126)2.82kΩ = 78.2kΩ ⎤ 126(2820) 78.2kΩ ⎡ ⎥ = 0.978 ⎢ = 1kΩ + 78.2kΩ ⎢⎣ 350 + 3130 + 126(2820)⎥⎦ 16.36 125(0.025V ) rπ = = 31.25kΩ | g m = 40(0.1mA)= 4mS 0.1mA r +r 200Ω + 31.25kΩ = 248Ω | RL = 22kΩ 75kΩ = 17.0kΩ Rin = RE x π = 43kΩ 126 βo + 1 Rin 248Ω g m RL = (4mS )(17.0kΩ)= 48.5 100Ω + 248Ω RI + Rin (a) A = (b) R = RE mid in 03/09/2007 247Ω rπ 31.25kΩ = 43kΩ = 247Ω | Amid = (4mS )(17.0kΩ)= 48.4 100Ω + 247Ω 126 βo + 1 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-21 16.37 (a) s 2 s= + 5100s + 500000 | s1 ≅ − ( −5100 ± 51002 − 4 5x105 5100 5x105 = −5100 | s2 ≅ − = −98.0 1 5100 ) = −5100 ± 4900 → −100, 2 2 2 2 (b) 2s + 700s + 30000 = 2 s + 350s + 15000 ( s1 ≅ − − 5000 | 2% error ) 350 15000 = −350 | s2 ≅ − = −42.9 1 350 −350 ± 3502 − 4(15000) −350 ± 250 → −50, − 300 | 14% error 2 2 3300 3x105 2 3s + 3300s + 300000 | s ≅ − = −1100 | s ≅ − = −90.9 c () 1 2 3 3300 s= s= = ( −3300 ± 33002 − 4(3) 3x105 ) = −3300 ± 2700 → −100, 6 6 2 2 (d ) 0.5s + 300s + 40000 = 0.5 s + 600s + 80000 ( s1 ≅ − s= −1000 | 11% error ) 600 80000 = −600 | s2 ≅ − = −133 1 600 −600 ± 6002 − 4(80000) 2 = −600 ± 200 → −200, − 400 | 34%, 50% error 2 16.38 s3 + 1110s2 + 111000s + 1000000 1110 111000 1000000 = −1110 | s2 ≅ − = −100 | s3 ≅ − = −9.01 1 1110 111000 Factoring the polynomial : s3 + 1110s2 + 111000s + 1000000 = (s + 10)(s + 100)(s + 1000) s1 ≅ − s = −1000, −100, −10 | 11% error in s1 , 10% error in s3 In MATLAB: roots([1 1110 111000 1000000]) 16.39 f (s) = s6 + 142s 5 + 4757s 4 + 58230s3 + 256950s2 + 398000s + 300000 f ' (s)= 6s5 + 710s 4 + 19028s 3 + 174690s2 + 513900s + 398000 s i +1 =s − i () f (s ) f si ' i | Using a spreadsheet, four real roots are found : -100, - 20, -15, - 5 Using MATLAB: roots([1 142 4757 58230 256950 398000 300000]) ans = -100, -20, -15, -5, -1+i, -1-i 17-22 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.40 r RI 1kΩ v π Cµ 300 Ω Rin r RB π = 100(0.025) 0.001 Ω 2500 + + i 7.5 k Ω (a) r x v 1 RC 2 gm v1 - - 4.3 k Ω R3 100 k Ω ( ) − 0.75 pF = 12.0 pF 2π (5x10 ) = 4.3kΩ 100kΩ = 4.12kΩ | g = 40(10 )= 40mS = 2500Ω | Cµ = 0.75 pF | Cπ = Rin = 7.5kΩ (rx + rπ ) = 2.03kΩ | RL v Cπ 40 10−3 8 −3 m ⎛ Rin ⎞⎛ rπ ⎞ ⎛ 2.03kΩ ⎞⎛ ⎞ 2500Ω Amid = −⎜ ⎟⎜ ⎟ g m RL = −⎜ ⎟⎜ ⎟(40mS )(4.12kΩ)= −98.6 ⎝1kΩ + 2.03kΩ ⎠⎝ 300Ω + 2500Ω ⎠ ⎝ RI + Rin ⎠⎝ rx + rπ ⎠ 1 ωH = | rπo = rπ rx + RB RI = 2500 300 + 7500 1000 = 803 Ω rπoCT ⎡ 4120⎤ 1 = 1.42 MHz CT = 12.0 + 0.75 ⎢1+ 40 10−3 (4120)+ ⎥ = 140 pF | f H = 803 ⎦ ⎣ 2π (803) 1.4x10−10 [ ( )] ( ) (b) GBW = 98.6(1.42 MHz)= 140 MHz 03/09/2007 [ ( )] ( ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 ) 17-23 16.41 +12 V RC R2 2.15 k Ω 15 k Ω R1 RE 5k Ω 650 Ω (a) 5kΩ = 3V | REQ = 5kΩ 15kΩ = 3.75kΩ 5kΩ + 15kΩ VEQ − VBE (3 − 0.7)V IC = β F IB = β F = 100 = 3.31 mA 3.75kΩ + (101)(0.65kΩ) REQ + (β F + 1)RE VEQ = 12V ⎛ ⎞ 101 VCE = VCC − IC RC − IE RE = 12 − (3.31mA)⎜ 2.15kΩ + 0.65kΩ⎟ = 2.71 V | Q - Point : (3.31 mA, 2.71 V ) ⎝ ⎠ 100 (b) r RI 1kΩ v x Cµ 300 Ω Rin RB + + v rπ i 1 2 gm v 1 - - 3.75 k Ω RC v Cπ R 3 2.15 k Ω 100 k Ω Note: As designers, we are free to change the amplifier design, but we typically cannot change the characteristics of the source and load resistances. 40(3.31x10−3 ) 100(0.025) rπ = = 755Ω | Cµ = 0.75 pF | Cπ = − 0.75 pF = 41.4 pF 3.31mA 2π (5x10 8 ) Rin = 3.75kΩ (rx + rπ ) = 823Ω | RL = 2.15kΩ 100kΩ = 2.11kΩ gm = 40(3.31x10−3 )= 132mS Amid = − ωH = ⎛ ⎞⎛ ⎞ Rin ⎛ rπ ⎞ 823Ω 755Ω ⎟⎜ ⎟(132mS )(2.11kΩ) = −90.0 ⎜ ⎟gm RL = −⎜ ⎝1000Ω + 823Ω ⎠⎝ 300Ω + 755Ω ⎠ RI + Rin ⎝ rx + rπ ⎠ 1 rπoCT [ ] [ ] | rπo = rπ rx + (RB RI ) = 755Ω 300 + (3.75kΩ 1kΩ) = 260Ω ⎡ 2.11kΩ ⎤ 1 = 312 pF | f H = CT = 41.4 + 0.75 ⎢1+ (132mS )(2.11kΩ) + = 1.96 MHz ⎥ ⎣ 0.260kΩ⎦ 2π (260Ω)(3.12x10−10 F ) (c ) GBW 17-24 = 90.0(1.96MHz) = 176 MHz | GBW ≤ 1 ⎛ 1 ⎞ 1 = 707 MHz ⎜⎜ ⎟⎟ = 2π ⎝ rx Cµ ⎠ 2π (300Ω)(0.75 pF ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.42 +12 V RC R2 215 k Ω 1.5 M Ω R1 RE 500 k Ω 65 k Ω (a) r RI 50 k Ω RB 375 k Ω Cµ 300 Ω Rin vi x rπ + + v - 1 v Cπ 2 gm v1 - (b) RC R3 215 k Ω 5 M Ω 500kΩ = 3V | REQ = 500kΩ 1.5MΩ = 3.75kΩ 500kΩ + 1.5MΩ VEQ − VBE (3 − 0.7)V = 100 = 33.1 µA IC = β F I B = β F 375kΩ + (101)(65kΩ) REQ + (β F + 1)RE VEQ = 12V ⎛ ⎞ 101 VCE = VCC − IC RC − I E RE = 12 − (33.1µA)⎜ 215kΩ + 65kΩ⎟ = 2.71 V | Q - Point : (33.1 µA, 2.71 V ) 100 ⎝ ⎠ Note: As designers, we are free to change the amplifier design, but we typically cannot change the characteristics of the source and load resistances. However, the problem statement indicated changing all resistors. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-25 rπ = 100(0.025) 33.1µA = 75.5kΩ | Cµ = 0.75 pF | Cπ = ( 40 33.1x10−6 ( 2π 5x10 8 ) )− 0.75 pF = −0.329 pF The constant fT model is breaking down at low currents. Set Cπ = 0 Rin = 375kΩ (rx + rπ ) = 63.1kΩ | RL = 215kΩ 5MΩ = 211kΩ Amid = − ωH = ( - not possible. ) | g m = 40 33.1x10−6 = 1.32mS ⎛ ⎞⎛ ⎞ 75.5kΩ Rin ⎛ rπ ⎞ 63.1kΩ ⎜ ⎟ g m RL = −⎜ ⎟⎜ ⎟(1.32mS )(211kΩ) = −155.0 RI + Rin ⎝ rx + rπ ⎠ ⎝ 50kΩ + 63.1kΩ ⎠⎝ 300Ω + 75.5kΩ ⎠ 1 rπoCT [ ( | rπo = rπ rx + RB RI )]= 75.5kΩ [300 + (375kΩ 50kΩ)]= 28.0kΩ ⎡ 211kΩ ⎤ 1 CT = 0 + 0.75 ⎢1+ (1.32mS )(211kΩ)+ = 24.9 kHz ⎥ = 228 pF | f H = 8.86kΩ⎦ ⎣ 2π (28.0kΩ) 2.28x10−10 F ( (c) GBW = 155(24.9kHz)= 3.86 MHz | 17-26 GBW ≤ ) 1 ⎛ 1 ⎞ 1 = 707 MHz ⎜⎜ ⎟⎟ = 2π ⎝ rx Cµ ⎠ 2π (300Ω)(0.75 pF ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.43 Rin = R1 R2 = 4.3MΩ 5.6 MΩ = 2.43MΩ | RL = 43kΩ 470kΩ = 39.4kΩ gm = 2(0.2mA) 2I D = = 0.400mS | VGS − VTN 1 Amid = − fH = Rin 2.43MΩ g m RL = − 0.400mS (39.4kΩ)= −15.7 2kΩ + 2.43MΩ RI + Rin 1 2πrπoCT | rπo = R1 R2 RI = 2.00kΩ ⎡ 39.4kΩ⎤ CT = 2.5 pF + 2.5 pF ⎢1+ (0.400mS )(39.4kΩ)+ ⎥ = 93.7 pF 2kΩ ⎦ ⎣ fH = ( 1 2π (2kΩ) 93.7x10−12 F ) = 849 kHz 16.44 *Problem 16.44 - Common-Source Amplifier VDD 7 0 DC 0 VS 1 0 AC 1 RS 1 2 2K C1 2 3 0.1UF R1 3 0 4.3MEG R2 3 7 5.6MEG RD 7 5 43K R4 4 0 13K C3 4 0 10UF C2 5 6 0.1UF R3 6 0 1MEG *Small-Signal FET Model GM 5 4 3 4 0.4MS CGS 3 4 2.5PF CGD 3 5 2.5PF * .AC DEC 20 1 10MEG .PRINT AC VM(6) .PROBE .END Results: Amid = -15.7, fL = 8.52 Hz, fH = 866 MHz 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-27 16.45 V DD = 12 V RD R2 10 k Ω 560 k Ω R1 RS 430 k Ω 3.9 k Ω (a) 430kΩ = 5.21V | REQ = 430kΩ 560kΩ = 243kΩ 430kΩ + 560kΩ K 2 Assume active region operation : ID = n (VGS − VTN ) | VEQ = VGS + ID RS 2 ⎛ 0.5mA ⎞ 2 5.21 = VGS + 3.9kΩ⎜ ⎟(VGS −1) → VGS = 2.629V and ID = 663µA ⎝ 2 ⎠ VEQ = 12V VDS = VDD − ID RD − IS RS = 12 − (663µA)(13kΩ + 3.9kΩ) = 0.795 V The transistor is not in pinch off! Reduce RD to 10 kΩ. VDS = VDD − ID RD − IS RS = 12 − (663µA)(10kΩ + 3.9kΩ) = 2.78 V - Active region is correct. RI 1kΩ CGD RG vi 243 k Ω + + Rin v 1 - CGS v RD R3 10 k Ω 100 k Ω 2 g mv 1 - (b) Rin = R1 R2 = 430kΩ 560kΩ = 243kΩ | RL = 10kΩ 100kΩ = 9.09kΩ gm = 2(0.663mA) 2ID = = 1.33mS VGS − VTN 1 Amid = − fH = Rin 243kΩ gm RL = − (1.33mS )(9.09kΩ) = −12.0 1kΩ + 243kΩ RI + Rin 1 2πrπoCT | rπo = R1 R2 RI = 243kΩ 1kΩ = 0.996kΩ ⎡ 9.09kΩ ⎤ CT = 2.5 pF + 2.5 pF ⎢1+ (1.33mS)(9.09kΩ) + = 58.1pF ⎣ 0.996kΩ⎥⎦ 1 = 2.75 MHz fH = 2π (0.996kΩ)(58.1x10−11 F ) (c ) GBW 17-28 = 12.0(2.75 MHz) = 33 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.46 r RI 1kΩ x Cµ 300 Ω Rin RB vi + + v rπ 1 g m = 40IC = 40(0.164mA) = 6.56mS | rπ = βo gm 2 gm v 1 - - 75 k Ω v Cπ = RC R3 43 k Ω 43 k Ω 100 = 15.2kΩ | ro = ∞ (VA not given ) 6.56mS Rin = R1 R2 rπ = 100kΩ 300kΩ 15.2kΩ = 12.6kΩ | RL = RC R3 = 43kΩ 43kΩ = 21.5kΩ Amid = − Cπ = ωH = gm ωT Rin 12.6kΩ g m RL = − (6.56mS )(21.5kΩ)= −131 1kΩ + 12.6kΩ RI + Rin − Cµ = 1 rπoCT 6.56mS ( 2π 5x108 Hz ) − 0.75 = 1.34 pF ( ) | rπo = rπ rx + R1 R2 RI = 15.2 kΩ (300 + 987)= 1.19 kΩ ⎛ ⎡ R ⎞ 21.5kΩ⎤ CT = Cπ + Cµ ⎜1+ g m RL + L ⎟ = 1.34 pF + 0.75 pF ⎢1+ 6.56mS (21.5kΩ)+ ⎥ = 121pF 1.19kΩ ⎦ rπo ⎠ ⎣ ⎝ 1 = 1.10 MHz fH ≅ 2π (1.19kΩ) 1.21x10−10 F ( ) 16.47 *Problem 16.47 - Common-Emitter Amplifier VCC 7 0 DC 0 VS 1 0 AC 1 RS 1 2 1K C1 2 3 5UF R1 3 0 300K R2 3 7 100K RC 5 0 43K R4 7 4 13K C2 7 4 22UF C3 5 6 1UF R3 6 0 43K *Small-signal Model for the BJT GM 5 4 8 4 6.56MS RX 3 8 0.3K RPI 8 4 15.24K CPI 8 4 1.34PF 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-29 CU 8 5 0.75PF * .AC DEC 100 1 10MEG .PRINT AC VM(6) .PROBE .END Results: Amid = -128, fL = 47 Hz, fH = 1.10 MHz 16.48 (a ) See Eqs. (16.88 -16.96). ⎤ ⎡V (s)⎤ ⎡I (s)⎤ ⎡s(C + C )+ g −sC ⎥⎢ ⎥ ⎢ ⎥=⎢ s(C + C )+ g ⎥⎦ ⎢⎣V (s)⎥⎦ ⎣ 0 ⎦ ⎢⎣ −(sC − g ) ∆ = s [C (C + C )+ C C ]+ s[C g + C (g + g + g )+ C g ]+ g g π S µ µ 2 (b) ω π P1 ω P2 ≅ ≅ µ L πo µ µ m µ L 1 L π L 2 L µ m g L g πo = Cπ g L + Cµ (g m + g πo + g L )+ CL g πo Cπ g L + Cµ (g m + g πo + g L )+ CL g πo Cπ (Cµ + CL )+ Cµ CL = πo L L πo L πo 1 ⎡ R⎤ rπo ⎢Cπ + Cµ (1+ g m RL )+ (Cµ + CL ) L ⎥ rπo ⎦ ⎣ gm ⎛ C ⎞ Cπ ⎜⎜1+ L ⎟⎟ + CL ⎝ Cµ ⎠ (c) The three capacitors form a loop, and there are only two independent voltages among the three capacitors. 16.49 CT = Cπ + Cµ (1+ g m RL )= 20 pF + 1pF 1+ 40(1mA)(1kΩ) = 61 pF [ fT = ] 1 ⎛ g m ⎞ 1 ⎡ 40(1mA) ⎤ ⎥ = 303 MHz ⎢ ⎜ ⎟= 2π ⎜⎝ Cπ + Cµ ⎟⎠ 2π ⎢⎣ 20 pF + 1pF ⎥⎦ 17-30 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.50 ( ) 1+ A 1+ A = = sC(1+ A) | Cin = C (1+ A)= 10−10 F 1+ 105 = 10 µF 1 Z (s) sC Z (s) s + 10 s + 10 1 105 (b) Zin = Y = 1+ A s = 106 = 105 s + 10 + 106 ≅ 105 s + 106 ( ) 1+ in s + 10 Using MATLAB : Zin (j2000π )= (4.95 + j6.28) Ω (a) Y in ( = ) ( ) Zin j105 π = (8.98 + j28.6) kΩ | Zin j2πx106 = (97.5 + j15.5) kΩ 16.51 10 Ao s + 10 ⎛ 1 ⎞ A(s) 10 Ao ⎟ ⎜ 1+ ⎛ 1 ⎞ ⎝ RC ⎠ 1+ A(s) 10 Ao s + 10 | A(s) = | Av (s)= ⎜ (a) Av (s)= ⎟ 1 1 s + 10 RC ⎠ ⎝ s+ s+ ⎛ 10 Ao ⎞ RC 1+ A(s) RC⎜1+ ⎟ ⎝ s + 10 ⎠ ⎛ 10 Ao ⎞ ⎟ ⎜ ⎛ 1 ⎞ 10 Ao ⎝ RC ⎠ Av (s) = ⎜ = ⎟ ⎡ 1 ⎤ 10 ⎝ RC ⎠ s2 + s 1+ A 10 + s + 10 + 10(1+ Ao )⎥ + ( o ) RC s2 + s⎢ RC ⎣ ⎦ RC ⎛ 106 ⎞ ⎛ 106 ⎞ ⎟ ⎟ ⎜ ⎜ 1 ⎝ RC ⎠ ⎝ RC ⎠ Av (s) = ≅ ; ωL = 5 ⎛ ⎡ 1 ⎤ 10 1 ⎞ 10 RC s2 + s⎢ s + 106 ⎜ s + 5 + 106⎥ + ⎟ ⎣ RC ⎦ RC ⎝ 10 RC ⎠ 7 ⎛ 10 ⎞ ⎛ 106 ⎞ ⎟ ⎟ ⎜ ⎜ 1 ⎝ RC ⎠ ⎝ RC ⎠ ≅ ; ωL = 6 (b) Av (s)= ⎛ ⎡ 1 ⎤ 10 1 ⎞ 10 RC s2 + s⎢ s + 10 7 ⎜ s + 6 + 10 7 ⎥ + ⎟ ⎣ RC ⎦ RC ⎝ 10 RC ⎠ ⎛10 Ao ⎞ ⎟ ⎜ 1 ⎝ RC ⎠ (c) lim Av (s)= 10 A s = sRC Ao →∞ o [ ] ( ) ( 03/09/2007 ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-31 16.52 250 Ω r x C rπ vi 2500 T Ω ⎡ 2500⎤ rπo = 2500Ω 250Ω = 227Ω | CT = 15 + 1⎢1+ 0.04(2500)+ ⎥ = 127 pF 227 ⎦ ⎣ (a) At 1 kHz, Z = C 1 ( ) j (2π ) 10 (127 pF ) 3 Using MATLAB : Z = 250 + (b) At 50 kHz, Z C = (c) At 1 MHz, Z C = ) j (2π ) 5x10 (127 pF ) 4 Using MATLAB : Z = 250 + 1 ( ) ) 2500ZC = (2750 − j4.99) Ω | SPICE : (2750 − j4.56) Ω 2500 + ZC 1 ( ( = − j 1.25x106 = − j2.51x10 4 Ω 2500ZC = (2730 − j247) Ω | SPICE : (2730 − j226) Ω 2500 + ZC j (2π ) 106 (127 pF ) = − j (12.53) 2500ZC = (752 − j1000) Ω | SPICE : (836 − j1040) Ω 2500 + ZC (d) *Problem 16.52 - Common-Emitter Amplifier IS 0 1 AC 1 RX 1 2 0.25K RPI 2 0 2.5K CPI 2 0 15PF CU 2 3 1PF GM 3 0 2 0 40MS RL 3 0 2.5K .AC LIN 1 1KHZ 1KHZ *.AC LIN 1 50KHZ 50KHZ *.AC LIN 1 1MEG 1MEG .PRINT AC VR(1) VI(1) VM(1) VP(1) .END Using MATLAB : Z = 250 + Note that the CT approximation does not provide as good an estimate of Zin at high frequencies (note the discrepancy at 1 MHz). 16.53 Amid = 39.2 dB, fL = 0 Hz, fH = 5.53 MHz 16.54 17-32 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 (a) g m = 40IC = 40(1mA) = 40.0mS | rπ = [ ( rπo = rπ rx + RB RI Cπ = gm ωT − Cµ = β oVT IC = 125(0.025) 1mA = 3.13kΩ | ro = ∞ (VA not given ) )]= 3.13kΩ (500 + (7.5kΩ 1kΩ))= 959Ω 40.0mS ( 2π 5x10 Hz 8 ) − 0.75 pF = 12.0 pF | f H ≅ | RL = RC R3 = 4.3kΩ 100kΩ = 4.12kΩ 1 2π rπoCT ⎛ ⎡ R ⎞ 4.12kΩ ⎤ CT = Cπ + Cµ ⎜1+ g m RL + L ⎟ = 12.0 pF + 0.75 pF ⎢1+ 40.0mS (4.12kΩ)+ ⎥ = 140 pF 0.959kΩ⎦ rπo ⎠ ⎣ ⎝ fH ≅ (b) r 1 ( [r + (R 2π (959Ω) 1.40x10−10 F πo = rπ x B RI ) = 1.19 MHz )]= 3.13kΩ (0 + (7.5kΩ 1kΩ))= 688Ω ⎡ 4.12kΩ ⎤ CT = 12.0 pF + 0.75 pF ⎢1+ 40.0mS (4.12kΩ)+ ⎥ = 141pF 0.688kΩ⎦ ⎣ fH ≅ 1 ( 2π (688Ω) 1.41x10−10 F 03/09/2007 ) = 1.64 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-33 16.55 r RI 1kΩ x Cµ 400 Ω Rin RB vi v rπ m = 40IC = 40(0.1mA)= 4.00mS | rπ = [ ( rπo = rπ rx + RB RI 1 β oVT IC 100(0.025) 0.1mA R3 43 k Ω 100 k Ω 2 gm v1 - = RC v Cπ - 75 k Ω (a) g + + = 25kΩ | ro = ∞ (VA not given ) )]= 25kΩ (400 + (75kΩ 1kΩ))= 1.31kΩ Rin = R1 R2 (rx + rπ ) = 100kΩ 300kΩ 25.4kΩ = 19.0kΩ | RL = RC R3 = 43kΩ 100kΩ = 30.1kΩ Amid = − Cπ = gm ωT Rin 19.0kΩ g m RL = − (4.00mS )(30.1kΩ)= −114 1kΩ + 19.0kΩ RI + Rin − Cµ = 4.00mS ( 2π 5x10 Hz 8 ) − 0.75 pF = 0.523 pF | f H ≅ 1 2π rπoCT ⎛ ⎡ R ⎞ 30.1kΩ⎤ CT = Cπ + Cµ ⎜1+ g m RL + L ⎟ = 0.523 pF + 0.75 pF ⎢1+ 4.00mS (30.1kΩ)+ ⎥ = 109 pF rπo ⎠ 1.31kΩ ⎦ ⎣ ⎝ fH ≅ 1 ( 2π (1.31kΩ) 1.09x10−10 F ) = 1.12 MHz (b) GBW = 114(1.12 MHz)= 128 MHz | 1 1 = = 531 MHz 2π rx Cµ 2π (400Ω)(0.75 pF ) 16.56 Rin = R1 R2 = 4.3MΩ 5.6 MΩ = 2.43MΩ | RL = 43kΩ 470kΩ = 39.4kΩ gm = 2(0.2mA) 2I D = = 0.400mS | VGS − VTN 1 Amid = − fH = Rin 2.43MΩ g m RL = − 0.400mS (39.4kΩ) = −15.7 RI + Rin 2kΩ + 2.43MΩ 1 2πrπoCT | rπo = R1 R2 RI = 2.00kΩ ⎡ 39.7kΩ⎤ CT = 5 pF + 2 pF ⎢1+ (0.400mS )(39.7kΩ)+ ⎥ = 78.5 pF 2kΩ ⎦ ⎣ fH = ( 1 2π (2kΩ) 78.5x10−12 F 17-34 ) = 1.01 MHz | GBW = 15.7(1.01 MHz)= 15.9 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.57 Problem 16.57 should refer to Fig. 16.34, ot Fig. 1631. 1 1 1 = | CT = = 48.5 pF fH = 2πrπoCT 2π (656Ω)CT 2π (656Ω)(5MHz) ⎛ ⎡ R⎤ 1 ⎞ C − Cπ 48.5 pF −19.9 pF CT = Cπ + Cµ ⎢1+ g m RL + L ⎥ | RL ⎜ g m + ⎟ = T −1 = −1 = 56.2 rπo ⎦ Cµ rπo ⎠ 0.5 pF ⎣ ⎝ RL = 56.2 ⎛ 1 ⎞ ⎜.064S + ⎟ 656Ω ⎠ ⎝ = 858Ω | RL = RC 100kΩ → RC = 865Ω 100(858Ω) = −31.9 | GBW = 31.9(5MHz)= 160 MHz 882Ω + 250Ω + 1560Ω The nearest 5% value is RC = 820 Ω | RL = 820Ω 100kΩ = 813Ω Amid = − Amid = − fH = 100(813Ω) ⎡ 813⎤ = −30.2 | CT = 19.9 + 0.5⎢1+ 0.064(813)+ ⎥ = 47.0 pF 882Ω + 250Ω + 1560Ω 656 ⎦ ⎣ 1 1 = = 5.16 MHz | GBW = 156 MHz 2πrπoCT 2π (656Ω)(47.0 pF ) 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-35 16.58 +12 V 43 k Ω 100 Ω 43 k Ω 100 k Ω 75 k Ω 30.1 k Ω Rin vi 75 k Ω 3V 3kΩ 13 k Ω IC = 100 3 − 0.7 = 0.166mA | VCE = 12 − 43kΩIC −13kΩI E = 2.70 V 75kΩ + 101(13kΩ) g m = 40(0.166mA)= 6.64mS rπ 0 = 100 = 15.1kΩ 6.64mS Cπ = gm ωT − Cµ = 3.02 pF Short-Circuit Time Constants [ ] R1S = 100Ω + 75kΩ 300Ω + 15.1kΩ + 101(3kΩ) = 60.8kΩ ⎛ 15.1kΩ + 99.9Ω ⎞ R2S = 10kΩ ⎜ 3kΩ + ⎟ = 2.40kΩ 101 ⎠ ⎝ R3S = 43kΩ + 100kΩ = 143kΩ ⎤ 1 1 ⎡ 1 1 ⎢ ⎥ = 43.9Hz + + fL ≈ 2π ⎢⎣(60.8kΩ)(1µF ) (2.40kΩ)(2.2µF ) (143kΩ)(0.1µF )⎥⎦ Open-Circuit Time Constants [ ( )] Using the results from Table 16.2 on page 1037 : rπ 0 = 15.1kΩ 300 + 100 75kΩ = 390 Ω ⎡ (6.64mS )(30.1kΩ) 30.1kΩ⎤ 3.02 pF ⎥ CTB = + 0.5 pF ⎢1+ + 1+ (6.64mS )(3kΩ) ⎢⎣ 1+ (6.64mS )(3kΩ) 390Ω ⎥⎦ CTB = 44.0 pF | f H = (b) A 17-36 mid 1 = 9.27 MHz 2π (390Ω)(44.0 pF ) ⎛ 60.7kΩ ⎞ (6.64mS )(30.1kΩ) = −⎜ = −9.54 GBW = 9.54(9.27 MHz − 43.9Hz)= 88.0 MHz ⎟ ⎝ 60.8kΩ ⎠ 1+ (6.64mS )(3kΩ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.59 Using the results from Table 16.2 on page 1037 and Prob. 16.58 1 = 54.4 rπ 0 = 15.1kΩ 300 + 100 75kΩ = 390 Ω CTB = 2π (7.5MHz)(390Ω) [ CTB = ( )] ⎡ (6.64mS )(30.1kΩ) 30.1kΩ⎤ 3.02 pF ⎥ = 54.4 pF + 0.5 pF ⎢1+ + 390Ω ⎥⎦ 1+ (6.64mS )RE 1+ (6.64mS )RE ⎢⎣ Using MATLAB : RE = 862 Ω Amid = 0.999 −100(30.1kΩ) 99.9Ω + 300Ω + 15.1kΩ + 101(862Ω) = −29.3 | GBW = 220 MHz The closest 5% resistor values are RE = 820 Ω and R6 = 12 kΩ ⎡ (6.64mS )(30.1kΩ) + 30.1kΩ⎤⎥ = 55.1 pF 3.02 pF + 0.5 pF ⎢1+ CTB = 1+ (6.64mS )0.82kΩ ⎢⎣ 1+ (6.64mS )0.82kΩ 390Ω ⎥⎦ fH = 1 = 7.41MHz 2π (390Ω)(55.1pF ) Amid = 0.999 −100(30.1kΩ) = −30.6 | GBW = 227 MHz 99.9Ω + 300Ω + 15.1kΩ + 101(0.82kΩ) Note: The Q-point will actually change somewhat and this has been neglected. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-37 16.60 ⎡ ⎤ ⎛I ⎞ 3 − 0.7 ⎢ ⎥ (a) IC = 100⎢7.5kΩ + 101 1.3kΩ ⎥ = 1.66mA | VCE = 12 − 4.3kΩ(IC )−1.3kΩ⎜⎝ αC ⎟⎠ = 2.69V ( )⎦ F ⎣ 2.69V ≥ 0.7V Active region operation is correct. | rπ = g m = 40(1.66 mA)= 66.4mS | Cπ = 66.4mS ( 2π 2x108 ) 100(0.025) 1.66 mA = 1.51 kΩ −1 = 51.8 pF | rx = 300Ω | Cµ = 1.0 pF +12 V 4.3 k Ω 250 Ω 4.3 k Ω 47 k Ω 7.5 k Ω 3.94 k Ω Rin vi 7.5 k Ω 3V 200 Ω 1.3 k Ω [ ] [ ] Rin = R1 R2 rx + rπ + (β o + 1)RE1 = 10kΩ 30kΩ 0.350kΩ + 1.51kΩ + (101)200Ω = 5.60 kΩ Rth = 7.5kΩ 250Ω = 242Ω | RL = 4.3kΩ 47kΩ = 3.94kΩ Amid = − ⎤ ⎡100(3.94kΩ)⎤ 5.60kΩ Rin ⎡ β o RL ⎥=− ⎥ = −16.9 ⎢ ⎢ 350Ω + 5.60kΩ ⎢⎣ 22.0kΩ ⎥⎦ RI + Rin ⎢⎣rx + rπ + (β o + 1)RE1 ⎥⎦ (b) Using the Short-Circuit Time Constants: R1S = 250Ω + 7.5kΩ 350Ω + 1.51kΩ + 101(200Ω) = 5.85kΩ [ ] R2S = 4.3kΩ + 43kΩ = 47.3kΩ ⎛ 1.51kΩ + 350 + 242Ω ⎞ R3S = 1.1kΩ ⎜ 200Ω + ⎟ = 184Ω 101 ⎝ ⎠ ⎤ 1 1 ⎡ 1 1 ⎢ ⎥ = 193Hz + + fL ≅ 2π ⎢⎣(5.85kΩ)(5µF ) (47.3kΩ)(1µF ) (184Ω)(4.7µF )⎥⎦ (c) Using the Open-Circuit Time Constants: Using the results from Table 16.2 on page 1037 : rπ 0 ≅ Rth + rx = 242Ω + 350Ω = 592Ω ⎡ (66.4mS )(3.94kΩ) + 3.94kΩ⎤⎥ = 29.6 pF 51.8 pF + 1pF ⎢1+ CTB = 1+ (66.4mS )(200Ω) ⎢⎣ 1+ (66.4mS )(200Ω) 592Ω ⎥⎦ CTB = 29.6 pF 17-38 fL = 1 = 9.08 MHz 2π (592Ω)(29.6 pF ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.61 Using the results in Table 16.2 on page 1037 and the values from Prob. 16.60 : rπ 0 ≅ Rth + rx = 242Ω + 350Ω = 592Ω | CTB = CTB = 1 = 22.4 pF 2π (592Ω)(12 MHz) ⎡ (66.4mS )(3.94kΩ) 3.94kΩ⎤ 51.8 ⎥ = 22.4 pF + 1pF ⎢1+ + 592Ω ⎥⎦ 1+ (66.4mS )RE 1+ (66.4mS )RE ⎢⎣ Using MATLAB : RE = 305 Ω The closest 5% resistor values are RE = 300 Ω and R6 = 1 kΩ ⎡ (66.4mS )(3.94kΩ) 3.94kΩ⎤ 51.8 pF ⎥ = 22.6 pF CTB = + 1pF ⎢1+ + 592Ω ⎥⎦ 1+ (66.4mS )300Ω ⎢⎣ 1+ (66.4mS )300Ω fH = 1 = 11.9 MHz 2π (592Ω)(22.6 pF ) [ ] [ ] Rin = R1 R2 rx + rπ + (β o + 1)RE1 = 10kΩ 30kΩ 0.300kΩ + 1.51kΩ + (101)300Ω = 6.08 kΩ Rth = 7.5kΩ 250Ω = 242Ω | RL = 4.3kΩ 47kΩ = 3.94kΩ Amid = − ⎡100(3.94kΩ)⎤ ⎤ Rin ⎡ β o RL 6.08kΩ ⎢ ⎢ ⎥=− ⎥ = −11.8 RI + Rin ⎢⎣rx + rπ + (β o + 1)RE1 ⎥⎦ 250Ω + 6.08kΩ ⎢⎣ 32.1kΩ ⎥⎦ 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-39 16.62 1k Ω 1k Ω R 2S R 1S 10 k Ω 1k Ω 1k Ω 1k Ω R 2O R 1O 1k Ω 10 k Ω 10 k Ω 1k Ω (a) SCTC: R1S = 10kΩ 1kΩ = 909Ω | R2S = 1kΩ 1kΩ = 500Ω | ω L = (b) OCTC: R1O = 10kΩ 2kΩ = 1.67kΩ | R2O = 1kΩ 11kΩ = 917Ω | ω H = 1 1 rad + = 1300 −6 −5 s 909(10 ) 500(10 ) 1 rad = 92.3 −5 s 1670(10 )+ 917(10 ) −6 (c) There are two poles. The SCTC technique assumes both are at low frequency and yields the largest pole. The OCTC assumes both are at high frequency and yields the smallest pole. (d ) ⎡(sC1 + G1 + G2 ) ⎢ −G2 ⎣ ⎤⎡V1 ⎤ −G2 ⎥⎢ ⎥ = 0 (sC2 + G2 + G3 )⎦⎣V2 ⎦ ∆ = s 2C1C2 + s[C2 (G1 + G2 ) + C1 (G2 + G3 )]+ G1G2 + G2G3 + G1G3 ∆ = s 210−11 + s(1.30x10−8 )+ 1.20x10−6 ∆ = s 2 + 1300s + 1.20x10 5 → s = −1200,−100 17-40 rad s ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.63 100 Ω R in vi 1.3 k Ω 4.3 k Ω 100 k Ω RL = 4.3kΩ 100kΩ = 4.12kΩ | CGS = 3.0 pF | CGD = 0.6 pF Rin = RS 1 1 = 1.3kΩ = 173Ω gm 5mS Rin 173Ω g m RL = (5ms)(4.12kΩ)= +13.1 RI + Rin 100Ω + 173Ω ⎛ ⎞ 1 1 ⎛ 1 ⎞ 1 ⎜ ⎟ = 64.4 MHz fH ≅ = ⎜ ⎟ 2π ⎝ CGD RL ⎠ 2π ⎜⎝ 0.6 pF (4.12kΩ)⎟⎠ Amid = 16.64 *Problem 16.12 - Common-Gate Amplifier - ac small-signal model VI 1 0 AC 1 RI 1 2 100 C1 2 3 4.7UF RS 3 0 1.3K RD 4 0 4.3K C2 4 5 1UF R3 5 0 100K G1 4 3 0 3 5mS .OP .AC DEC 100 0.01 100MEG .PRINT AC VM(5) VP(5) .END Results: Amid = +13.3, fL = 123 Hz, fH = 64.4 MHz 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-41 16.65 200 Ω vi Rin 2.2k Ω 4.3 k Ω 2.11 k Ω gm = 40(1 mA) = 0.04S | rx = 300Ω | rπ = Cπ = 40(10−3 ) 2π (5x10 8 ) Rin = RE Amid 51k Ω 100(0.025) = 2.50kΩ | Cµ = 0.6 pF 1 mA − 0.6 = 12.1 pF | Rth = 4.3kΩ 200Ω = 191Ω | RL = 2.2kΩ 51kΩ = 2.11kΩ (rx + rπ ) = 4.3kΩ (0.3kΩ + 2.50kΩ) = 27.6Ω βo + 1 101 100(2.11kΩ) Rin ⎛ β o RL ⎞ 27.6Ω = = +9.14 ⎜ ⎟= RI + Rin ⎝ rx + rπ ⎠ 200Ω + 27.6Ω 2.80kΩ 1 ωH = 191 fH = 17-42 ⎡ 0.04 (2110) ⎤ 12.1pF ⎛ 300 ⎞ ⎥ + 0.6 pF (2110Ω) ⎜1+ ⎟ + 0.6 pF (300Ω)⎢1+ 1+ 0.04 (191) ⎝ 191 ⎠ ⎣ 1+ 0.04 (191)⎦ ⎞ 1 ⎛ 1 = 40.9MHz ⎜ −10 −9 −9 ⎟ 2π ⎝ 6.876x10 + 1.938x10 + 1.266x10 ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.66 First, estimate the required SPICE parameters: 0.333 ⎛ CJC 2.8 ⎞ | CJC = CJC = 0.6 pF ⎜1+ ≅ 1.01pF Cµ = ⎟ ME ⎝ 0.75 ⎠ ⎛ VCB ⎞ ⎟ ⎜1+ ⎝ PHIE ⎠ C 1 Cµ 1 0.6 pF τF = π = − = 9 − = 303 ps gm ωT gm 10 π 40(1mA) *Figure P16.14 - Common-Base Amplifier VCC 6 0 DC 5 VEE 7 0 DC -5 VI 1 0 AC 1 RI 1 2 200 C1 2 3 4.7UF RE 3 7 4.3K Q1 4 0 3 NBJT RC 4 6 2.2K C2 4 5 1UF R3 5 0 51K .MODEL NBJT NPN BF=100 RB=300 CJC=1.01PF TF=303PS .OP .AC DEC 50 1 50MEG .PRINT AC VM(5) .PROBE .END Results: Amid = 19.1 dB, fL = 149 Hz, fH = 43.8 MHz 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-43 16.67 200 Ω Rin vi 2.2k Ω 4.3 k Ω IC = α F IE = 51k Ω 2.11 k Ω 100 ⎡−0.7 − (−10)⎤ ⎢ ⎥ = 2.14 mA | VCE = 10 − (2.14mA)(2.2kΩ) − (−0.7) = 5.99 V 101 ⎣ 4300 ⎦ gm = 40(2.14mA) = 85.6mS | rx = 300Ω | rπ = Cπ = 85.6mS − 0.6 = 26.7 pF | Rth = 4.3kΩ 200Ω = 191Ω | RL = 2.2kΩ 51kΩ = 2.11kΩ 2π (5x10 8 ) Rin = RE Amid = (rx + rπ ) = 4.3kΩ (0.3kΩ + 1.17kΩ) = 14.5Ω 101 1 191 17-44 βo + 1 100(2.11kΩ) 14.5Ω Rin ⎛ β o RL ⎞ = +9.70 ⎜ ⎟= RI + Rin ⎝ rx + rπ ⎠ 200Ω + 14.5Ω 1.47kΩ ωH = fH = 100(0.025) = 1.17kΩ | Cµ = 0.6 pF 2.14 mA ⎡ ⎛ 300 ⎞ 0.0856(2110) ⎤ 26.7 pF ⎥ + 0.6 pF (2110Ω) ⎜1+ ⎟ + 0.6 pF (300Ω)⎢1+ 1+ 0.0856(191) ⎝ 191 ⎠ ⎣ 1+ 0.0856(191)⎦ ⎞ 1 ⎛ 1 = 39.1 MHz ⎜ −10 −9 −9 ⎟ 2π ⎝ 7.556x10 + 2.054 x10 + 1.266x10 ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.68 2kΩ v i Rin 12 k Ω 22 k Ω 100 k Ω Rth = 12kΩ 2kΩ = 1.71kΩ | RL = 22kΩ 100kΩ = 18.0kΩ | CGS = 3.0 pF | CGD = 0.6 pF gm = 2(0.1mA) 1V = 0.200mS | Rin = 12kΩ 1 1 = 12kΩ = 3.53kΩ gm 0.200mS Rin 3.53kΩ g m RL = (0.200ms)(18.0kΩ)= +2.30 2kΩ + 3.53kΩ RI + Rin ⎛ ⎞ ⎞ ⎛ ⎜ ⎟ ⎟ ⎜ 1 1 ⎜ 1 1 ⎜ ⎟ = 10.9 MHz ⎟= fH = ⎜ ⎟ 3.0 pF 2π ⎜ CGS ⎟ 2π + CGD RL ⎟ + 0.6 pF (18.0kΩ)⎟ ⎜ ⎜ ⎠ ⎝ Gth + g m ⎝ (0.5848 + 0.200)mS ⎠ Amid = 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-45 16.69 (a) First find VTN and K n based upon Problem 16.21 1.5MΩ 12V = 4.87V | VGG − VGS = 0.1mA(12kΩ)→ VGS = 3.67V 1.5MΩ + 2.2 MΩ 2(0.1mA) 2I D = = 0.2mS VGS − VTN = 1V → VTN = 2.67V | Kn = 2 2 1 V − V ( ) VGG = GS TN 1.5MΩ 18V = 7.30V 1.5MΩ + 2.2 MΩ = 1.5MΩ 2.2 MΩ = 892kΩ | VGG − VGS = I D RS Now, find the Q - point for VDD = 18V : VGG = RGG ⎛ 0.2mS ⎞ 2 7.30 - VGS = (12kΩ)⎜ ⎟(VGS − 2.67) → VGS = 4.73V | I D = 0.254 mA | VDS = 9.37V ok ⎝ 2 ⎠ 2kΩ v i Rin 12 k Ω 22 k Ω 100 k Ω Rth = 12kΩ 2kΩ = 1.71kΩ | RL = 22kΩ 100kΩ = 18.0kΩ | CGS = 3.0 pF | CGD = 0.6 pF gm = 2(0.254mA) (4.26 − 2.67)V = 0.320mS | Rin = 12kΩ 1 1 = 12kΩ = 2.48kΩ gm 0.320mS Rin 2.48kΩ g m RL = (0.320ms)(18.0kΩ)= +3.19 2kΩ + 2.48kΩ RI + Rin ⎛ ⎞ ⎞ ⎛ ⎜ ⎟ ⎟ ⎜ 1 1 ⎜ 1 1 ⎜ ⎟ = 11.3 MHz ⎟= fH = ⎜ ⎟ 3.0 pF 2 π 2π ⎜ CGS ⎟ + CGD RL ⎟ + 0.6 pF (18.0kΩ)⎟ ⎜ ⎜ ⎠ ⎝ Gth + g m ⎝ (0.5848 + 0.32)mS ⎠ Amid = Note that the contribution of the input pole cannot be neglected because of the low fT of the MOSFET. R1S = RI + Rin = 4.48kΩ | R3S = R7 + Rout ≅ 100kΩ + 22kΩ = 122kΩ 1 ⎛ 1 1 ⎞ fL = + ⎟ = 20.6 Hz ⎜ 2π ⎝ R1S C1 R3S C3 ⎠ Note that the is no signal current in C2 , so it does not contribute to f L . 17-46 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.70 g m = 40(0.25 mA) = 10.0mS | rx = 300Ω | rπ = Cµ = 0.6 pF | Cπ = 0.01 ( 2π 5x108 ) 100(0.025) 0.25 mA = 10.0kΩ − 0.6 = 2.58 pF | RB = 100kΩ 300kΩ = 75.0kΩ RL = 13kΩ 100kΩ = 11.5kΩ | Rth = 75kΩ 2kΩ = 1.95kΩ [ ] [ ] Rin = RB rx + rπ + (β o + 1)RL = 75.0kΩ 300Ω + 10.0kΩ + (101)11.5kΩ = 70.5kΩ ⎛ Rin ⎞ 101(11.5kΩ) (β o + 1)RL = 0.972 Amid = ⎜ = 0.964 ⎟ 0.300 + 10.0 + 101(11.5) kΩ ⎝ RI + Rin ⎠ rx + rπ + (β o + 1)RL [ fH ≅ 1 2π 1 ⎤ ⎡ 2.58 pF ⎥ ⎢ 1950 + 300 + 0.6 pF ( )⎢1+ 10mS 11.5kΩ ⎥⎦ ( ) ⎣ ] = 1 1 = 114 MHz 2π (2250)(0.622 pF ) (b) Calculating the required SPICE parameters: ⎛ 11.8 ⎞ 0.333 CJC Cµ = | CJC = 0.6 pF ≅ 1.54 pF ⎟ ⎜1+ ME ⎝ 0.75 ⎠ ⎛ VCB ⎞ ⎟ ⎜1+ ⎝ PHIE ⎠ C 1 Cµ 1 0.6 pF τF = π = − = 9 − = 260 ps | TF = 260 ps gm ωT gm 10 π 40(0.25mA) *Problem 16.70 - Common-Collector Amplifier VCC 6 0 DC 15 VS 1 0 AC 1 RS 1 2 2K C1 2 3 4.7UF R1 3 0 100K R2 6 3 300K Q1 6 3 4 NBJT R4 4 0 13K C3 4 5 10UF R7 5 0 100K .MODEL NBJT NPN BF=100 TF=260PS CJC=1.54PF RB=300 .OP .AC DEC 100 0.1 200MEG .PRINT AC VM(5) VP(5) .END Results: Amid = 0.962, fL = 0.52 Hz, fH = 110 MHz 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-47 16.71 100kΩ = 2.25V | RB = 100kΩ 300kΩ = 75.0kΩ 100kΩ + 300kΩ (2.25 − 0.7)V = 0.251mA IC = 100 75.0kΩ + 101(13kΩ) VBB = 9V gm = 40(0.251mA) = 10.0mS | rx = 300Ω | rπ = Cµ = 0.6 pF | Cπ = 100(0.025) = 9.96kΩ 0.251mA 0.01 − 0.6 = 2.58 pF 2π (5x10 8 ) RL = 13kΩ 100kΩ = 11.5kΩ | Rth = 75kΩ 2kΩ = 1.95kΩ Rin = RB [rx + rπ + (β o + 1)RL ] = 75.0kΩ [300Ω + 9.96kΩ + (101)11.5kΩ] = 70.5kΩ ⎛ Rin ⎞ 101(11.5kΩ) (β o + 1)RL Amid = ⎜ = 0.972 = 0.964 ⎟ ⎝ RI + Rin ⎠ rx + rπ + (β o + 1)RL [0.300 + 9.96 + 101(11.5)]kΩ fH ≅ 17-48 1 2π 1 ⎤ 2.58 pF + 0.6 pF ⎥ ⎦ ⎣1+ 10mS (11.5kΩ) ⎡ (1950 + 300)⎢ = 1 1 = 114 MHz 2π (2250)(0.622 pF ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.72 First, find the value of Kn required for I D = 0.1 mA 1.5MΩ 10V = 4.05V | VGG − VGS = 0.1mA(12kΩ) → VGS = 2.85V 1.5MΩ + 2.2 MΩ 2(0.1mA) 2I D mA = = 0.356 2 VGS − VTN = 0.75V → VTN = 2.10V | Kn = 2 2 V (VGS − VTN ) (0.75) VGG = gm = 2(0.1mA) 0.75V Amid = = 0.267mS | Rin = R1 R2 = 892kΩ | RL = 12kΩ 100kΩ = 10.7kΩ (0.267mS )(10.7kΩ) = +0.739 g m RL Rin = 0.998 RI + Rin 1+ g m RL 1+ (0.267mS )(10.7kΩ) From Table 16.2 on page 1037 : f H = f P1 = 1 = 0.379Hz 2π (894kΩ)(4.7µF ) (-2.62 dB) 1 ⎡ ⎤ 3 pF + 0.6 pF ⎥ 2π 2kΩ 892kΩ ⎢ ⎢⎣1+ (0.267mS )(10.7kΩ) ⎥⎦ ( fP2 = ) 1 ⎡ ⎛ ⎞⎤ 1 2π ⎢100kΩ + ⎜12kΩ ⎟⎥(0.1µF ) 0.267mS ⎠⎥⎦ ⎢⎣ ⎝ = 57.9 MHz = 15.5 Hz f L ≅ 15.5 Hz Note that a low frequency RHP zero makes the calculation of fH a very poor estimate for the FET case. See the analysis in Prob. 17.73 which shows ωz = gm/CGS. *Problem 16.72 - Common-Drain Amplifier VDD 6 0 DC 10 VS 1 0 AC 1 RS 1 2 2K C1 2 3 4.7UF R1 3 0 1.5MEG R2 6 3 2.2MEG M1 6 3 4 4 NFET R4 4 0 12K C3 4 5 0.1UF R7 5 0 100K .MODEL NFET NMOS VTO=2.10 KP=0.356MA CGSO=30NF CGDO=6NF .OP .AC DEC 100 1 500MEG .PRINT AC VM(5) VP(5) .END Results: Amid = 0.740, fL = 15.5 Hz, fH = 195MHz - Note that there is peaking in the response. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-49 16.73 First find VDD , VTN and Kn from Prob. 17.22 : VDD = VDS + I D RS = 10 V 1.5MΩ 10V = 4.05V | VGG − VGS = 0.1mA(12kΩ)→ VGS = 2.85V VGG = 1.5MΩ + 2.2 MΩ 2(0.1mA) 2I D mA = = 0.356 2 VGS − VTN = 0.75V → VTN = 2.10V | Kn = 2 2 V (VGS − VTN ) (0.75) Now find the new Q - point with VDD = 20 V. 1.5MΩ 20V = 8.11V | RGG = 1.5MΩ 2.2 MΩ = 892kΩ | VGG − VGS = I D RS 1.5MΩ + 2.2 MΩ ⎛ 0.356mA ⎞ 2 8.11- VGS = (12kΩ)⎜ ⎟(VGS − 2.10) → VGS = 3.56V | I D = 0.379 mA | VDS = 15.5 V ok 2 ⎝ 2V ⎠ VGG = gm = 2(0.379mA) (3.56 − 2.10)V Amid = = 0.519mS | Rin = R1 R2 = 892kΩ | RL = 12kΩ 100kΩ = 10.7kΩ (0.519mS )(10.7kΩ) = +0.846 g m RL Rin = 0.998 RI + Rin 1+ g m RL 1+ (0.519mS )(10.7kΩ) From Table 16.2 on page 1037 : f H = 17-50 (-1.46 dB) 1 ⎤ ⎡ 3 pF 2π 2kΩ 892kΩ ⎢ + 0.6 pF ⎥ ⎥⎦ ⎢⎣1+ (0.519mS )(10.7kΩ) ( ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 = 75.4 MHz 16.74 i1 ix vx Cµ rπ + gm v v - Cπ RL Ix = sCµVx + I1 | Vx = ⎛ ⎞ I1 I1 + ⎜ I1 + gm ⎟ RL (sCπ + gπ ) ⎝ (sCπ + gπ )⎠ Vx sCπ rπ RL + RL + rπ + β o RL sCπ rπ RL + rπ + (β o + 1)RL = = I1 sCπ rπ + 1 sCπ rπ + 1 1 1 sCπ rπ sCπ + + 1 r + (β o + 1)RL rπ + (β o + 1)RL (1+ gm RL ) rπ + (β o + 1)RL Y1 = = π ≅ for β o >> 1 Cπ rπ RL Cπ RL Z1 s +1 s +1 rπ + (β o + 1)RL (1+ gm RL ) Z1 = ⎞ ⎞ 1 ⎛ 1 Cπ RL 1 ⎛ 1 << 1 → ω << ⎜ + gm ⎟ but ⎜ + gm ⎟ > ωT Cπ ⎝ RL Cπ ⎝ RL (1+ gm RL ) ⎠ ⎠ Cπ 1 So, for ω << ωT , Y1 ≅ s + (1+ gm RL ) rπ + (β o + 1)RL ω Cin = Cµ + Cπ and Rin = rπ + (β o + 1)RL (1+ gm RL ) ω H is determined by the input capacitance Cin and the source resistance Rth + rx . 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-51 16.75 + ix v C GD vx C GS gm v vs RL Ix = sCGDVx + sCGS (Vx − VS ) | Vx = V + (sCGSV + gmV )RL | V = Ix = sCGDVx + sCGS Vx (1+ gm RL + sCGS RL ) | Note : VS = Vx (1+ gm RL + sCGS RL ) (sCGS + gm )RL (1+ gm RL + sCGS RL ) Vx ⎤ ⎡ ⎥ ⎢ CGS RL Ix 1 CGS C R C g ⎥ | = s⎢CGD + ≈ GS L = GS & m > ωT R C Vx 1+ gm RL 1+ s GS L ⎥ 1+ gm RL gm RL gm CGS ⎢ ⎢⎣ 1+ gm RL ⎥⎦ CGS g Assuming ω << ωT : CIN ≈ CGD + | Note the zero in VS at ω z = − m 1+ gm RL CGS 16.76 Av = −141 (43dB) | f H = 6x106 Hz | fT ≥ 2(141) 6x106 = 1.69 GHz ( GBW ≤ 1 rx Cµ | rx Cµ ≤ 1 ( 2π 1.69x109 Hz ) ) = 94.2 ps 16.77 Av = 100 (40dB) | f H = 40x106 Hz | f T ≥ 2(100) 4x10 7 = 8.00 GHz ( GBW ≤ 17-52 1 rx Cµ | rx Cµ ≤ ( 1 2π 8x109 Hz ) ) = 19.9 ps ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.78 Amid = g m RL | g m = 100 100 β = 1.00mS | rπ = o ≅ = 100kΩ 100kΩ g m 1.00mS Assume rπ >> rx | rπo = rπ rx ≅ rx 1 ωH = ⎡ ⎛ R ⎞⎤ rx ⎢Cπ + Cµ ⎜1+ g m RL + L ⎟⎥ rx ⎠⎦ ⎝ ⎣ rx Cµ (1+ g m RL )+ RLCµ = Cµ = 0.884 pF 1+ 1.01x10−3 rx 1 ωH ≅ 1 ⎛ R ⎞ rx Cµ ⎜1+ g m RL + L ⎟ rx ⎠ ⎝ | rx Cµ (1+ 100)+ 105 Cµ = ( ) 2π 25x106 = | Amid = ( 1 2π 1.8x10 6 ) = 8.84x10−8 (0.75pF, 177Ω) (0.5pF,760Ω) 16.79 1 RLCGD 1 rx Cµ (1+ g m RL )+ RLCµ | Cµ cannot exceed 0.884 pF for an ideal transistor with rx = 0. Other more realistic possibilities (Cu ,rx ): ωH ≅ = Rin g R g m RL ≅ m L RI + Rin 1+ g m RI ⎛ 1 ⎞ ⎛ 1 ⎞ | RL = Amid ⎜ + RI ⎟ = 20⎜ + 100⎟ ⎝ gm ⎠ ⎝ gm ⎠ 1 → g m = 164mS ⎞ ⎛ 1 −12 20⎜ + 100Ω⎟3x10 F ⎠ ⎝ gm ⎛ 1 ⎞ (164mS ) = 672 mA g2 RL = 20⎜ + 100⎟ = 2.12 kΩ | I D = m = ⎛ mS ⎞ 2Kn ⎝ 0.164 ⎠ 2⎜20 ⎟ ⎝ V ⎠ 2 Note that we cannot supply I D through RL since I D RL = 1420V >> VDD . RI C C2 1 vi L R RL S One Possibility: +V DD This is really not a realistic design. The current and power are far too high. We need to find an FET with a much higher Kn. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-53 16.80 1 1 = ⎡ ⎡ ⎤ ⎡ ⎡ R ⎤⎤ R ⎤ Rth ⎢CGS + CGD ⎢1+ g m RL + L ⎥⎥ 100⎢12 pF + 5 pF ⎢1+ g m RL + L ⎥⎥ 100 ⎦⎦ Rth ⎦⎦ ⎣ ⎣ ⎣ ⎣ ⎡ ⎤ 1 RL ⎢ 1 6 ⎥1 2π 25x10 = | g m RL + = −17 ⎡ ⎡ ⎥5 100 ⎢ 2π 25x106 (100)10−12 R ⎤⎤ ⎣ ⎦ 100⎢17 pF + 5 pF ⎢g m RL + L ⎥⎥ 100 ⎣ ⎦ ⎣ ⎦ ωH = ( ) gm = ( ) 9.33 g2 g2 − 0.01 → RL ≤ 933Ω | I D = m = m = 20g m2 2Kn 0.05 RL For strong inversion (for the square - law model to be valid), we desire (V GS − VTN ) ≥ 0.25V → I D ≥ 2 0.025 0.25) = 781 µA. ( 2 (0.015) = 2 g m must exceed 0.01S. Choose g m = 0.015S. I D RL = .05 = 4.5 mA. 9.33 = 1.87 kΩ | g m RL = 28.0 g m − .01 16.81 fH ≤ 1 1 = → f H ≤ 8.33 MHz 2πRLCµ 2π 12kΩ 47kΩ (2 pF ) ( ) 16.82 i r x1 b + rπ1 v1 - c u1 Q c π1 g m1 v RL i b 1 Q2 Cπ & C µ 1 1 r x2 +rπ 1 g 2 Cπ2 & C µ2 Use the open-circuit time-constant approach: 17-54 1 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 m1 Q 2 R L ⎡ (β o + 1)(rx 2 + rπ 2 ) ⎤⎛ ⎞ βo Rµ1O : v x ≅ ix rx1 − ix rx1⎢ RL ⎟ − (−ix RL ) ⎥⎜− ⎣ rπ 1 + (β o + 1)(rx 2 + rπ 2 )⎦⎝ rx 2 + rπ 2 ⎠ ⎡ ⎞⎤ ⎛ β o rπ 2 Rµ1O ≅ ix ⎢RL + rx1⎜1+ gm 2 RL ⎟⎥ assuming rx 2 << rπ 2 . ⎠⎦ ⎝ rπ 1 + β o rπ 2 ⎣ ⎛ 10 ⎞ 10 v β rπ 1 ≅ 10rπ 2 | β o = 100 | gm1 ≅ o = | Rµ1O = x = RL + rx1⎜1+ gm 2 RL ⎟ ⎝ 11 ⎠ rπ 1 rπ 2 ix Rπ 1O : Split ix and use superposition with rx 2 << rπ 2 : ⎡ ix rπ 1 (β o + 1)(rx 2 + rπ 2 ) ⎤ + ix ≅ i r v x ≅ ix rx1⎢1− + ⎥ x x1 rπ 1 + β o rπ 2 gπ 2 + 10gπ 2 ⎣ rπ 1 + (β o + 1)(rx 2 + rπ 2 )⎦ gπ 2 + gm1 v 10rx1 + rπ 2 Rπ 1O = x ≅ ix 11 Rπ 2O : The circuit is the same as that used for the CT calculation. (a) ⎛ ⎛ 1 ⎞ rπ 2 ⎞ Rπ 2O = rπ 2 ⎜ rx 2 + ⎟ ⎟ = rπ 2 ⎜ rx 2 + ⎝ gm1 ⎠ 10 ⎠ ⎝ Rµ 2O : The circuit is the same as that used for the CT calculation except the additional ib = ix /2 is returned back to the output : ⎛ R RL ⎞ Rµ 2O = Rπ 2O + Rπ 2O gm 2 RL + L = Rπ 2O ⎜1+ gm 2 RL + ⎟ 2 2Rπ 2O ⎠ ⎝ 1 ωH = ⎡ ⎛ 10 ⎛ ⎛10r + r ⎞ R ⎞ RL ⎞⎤ Cπ 1⎜ x1 π 2 ⎟ + Cµ1rx1⎜1+ gm 2 RL + L ⎟ + Rπ 2O ⎢Cπ 2 + Cµ 2 ⎜1+ gm 2 RL + ⎟⎥ ⎝ ⎠ 11 rx1 ⎠ 2Rπ 2O ⎠⎦ ⎝ 11 ⎝ ⎣ 100(0.025V ) r 50V = 2.50kΩ | Use RL = o 2 = = 25.0kΩ 1mA 2 2mA 40(10−4 ) 40(10−3 ) − 0.5 pF = 1.62 pF | Cπ 2 = − 0.5 pF = 20.7 pF Cπ 1 = 6x10 8 π 6x10 8 π ⎛ ⎛ r ⎞ 2.50kΩ ⎞ Rπ 2O = rπ 2 ⎜ rx 2 + π 2 ⎟ = 2.50kΩ ⎜ 300 + ⎟ = 451Ω ⎝ ⎝ 10 ⎠ 10 ⎠ rπ 2 = −1 ⎧ ⎛ 3kΩ + 2.5kΩ ⎞ ⎡ 25kΩ ⎤⎫ ⎟ + 0.5 pF (300Ω)⎢1+ 40mS (25kΩ) + ⎪ ⎪1.62 pF ⎜ ⎣ ⎝ ⎠ 11 300Ω⎥⎦⎪ 1 ⎪ fH = ⎬ = 393 kHz ⎨ ⎡ ⎛ 2π ⎪ 25kΩ ⎞⎤ ⎪ +451Ω⎢20.7 pF + 0.5 pF ⎜1+ 40mS (25kΩ) + ⎟⎥ ⎪⎭ ⎪⎩ ⎝ 902Ω ⎠⎦ ⎣ 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-55 (b) The circuit is almost the same except for two important changes: Cµ1 sees only rx1, and the ib = ix /2 is not returned to the output for Cµ 2 . ωH = 1 ⎡ ⎛ R ⎞⎤ 10r + r Cπ 1 x1 π 2 + Cµ1rx1 + Rπ 2O ⎢Cπ 2 + Cµ 2⎜1+ gm 2 RL + L ⎟⎥ 11 Rπ 2O ⎠⎦ ⎝ ⎣ −1 ⎫ ⎧ ⎛ 3kΩ + 2.5kΩ ⎞ ⎟ + 0.5 pF (300Ω) ⎪ ⎪1.62 pF ⎜ ⎝ ⎠ 11 ⎪ 1 ⎪ fH = ⎬ = 640kHz ⎨ ⎡ ⎛ 2π ⎪ 25kΩ ⎞⎤⎪ +451Ω⎢20.7 pF + 0.5 pF ⎜1+ 40mS (25kΩ) + ⎟⎥ ⎪⎩ ⎝ 451Ω ⎠⎦⎪⎭ ⎣ (c ) The C - C/C - E cascade offers significantly better bandwidth than the Darlington configuration because Cµ1 is not subject to Miller multiplication. (d) Improved bandwidth is one reason for the use of the C - C/C - E cascade in the 741 op - amp. 17-56 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.83 C R C u + v rπ cm v be ro Cπ - g v m be 2R EE CEE 2 Assume RL represents a differential-mode load between the collectors. Degradation of the CMRR starts with the zero in the common-mode gain transfer function. ⎡⎛ C ⎞ G ⎤ (sCπ + g m + g π )vcm = ⎢s⎜⎝Cπ + 2EE ⎟⎠ + g m + g π + g o + 2EE ⎥ve − g ovc ⎣ ⎦ (sC µ − g m )vcm = −(g m + g o )ve + (sCµ + g o + GC )v cm Keeping the dominant terms, the numerator poynomial is approximately ⎤ ⎛ C ⎞ ⎡⎛ C ⎞ G N ≅ s 2Cµ ⎜ Cπ + EE ⎟ + s⎢⎜ Cµ − EE ⎟ g m + Cπ g o ⎥ + g o g π − g m EE 2 ⎠ ⎣⎝ 2 ⎠ 2 ⎝ ⎦ Using dominant root factorization : ⎛ 1 1 ⎞ GEE − ⎟ ⎜ gogπ − g m ⎛ 1 1 ⎞ 1 ⎝ β oro 2REE ⎠ 2 ωZ ≅ =⎜ − ≅ ⎟ ⎛ ⎛ CEE ⎞ CEE ⎞ Cπ CEE ⎞ ⎝ β oro 2REE ⎠ ⎛ ⎜ Cµ − ⎜Cµ − ⎜Cµ − ⎟ g m + Cπ g o ⎟+ ⎟ 2 ⎠ 2 ⎠ µf 2 ⎠ ⎝ ⎝ ⎝ The dominant terms in the determinant are ⎡⎛ ⎤ ⎛ ⎛ C ⎞ C ⎞ C ⎞ ∆ = s 2Cµ ⎜ Cπ + EE ⎟ + sCµ g m + s⎜ Cπ + EE ⎟GC + g mGC = ⎢s⎜Cπ + EE ⎟ + g m ⎥[sCµ + GC ] 2 ⎠ 2 ⎠ 2 ⎠ ⎝ ⎝ ⎣⎝ ⎦ The high pole is in the vicinity of ωT . The dominant pole is ω Pcm = 1 . RC Cµ ⎛ 1 1 ⎞ At dc, the common - mode gain is approximately Acm = RC ⎜ − ⎟ ⎝ β oro 2REE ⎠ For zero base resistance rx , the dominant pole in the differential mode response is ⎛ 1 R ⎞ ω Pdm = and Adm = 0.5g m ⎜ RC L ⎟ ω Pdm and ω Pcm approximately cancel. ⎛ 2⎠ R ⎞ ⎝ ⎜ RC L ⎟Cµ 2⎠ ⎝ The CMRR reaches - 6 dB when C µ shorts the base to the collector. 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-57 50 + 10.1 = 611kΩ 10−4 ⎡ ⎛ 1 1 ⎞ 1 ⎤ 1 ⎥ = −2.02x10−4 (-73.9dB) ⎢ − − Acm = RC ⎜ = 6kΩ ⎟ ⎝ β oro 2REE ⎠ ⎢⎣100(611kΩ) 20 MΩ⎥⎦ ⎛ 100kΩ ⎞ Adm = −0.5 4x10−3 ⎜6kΩ ⎟ = −10.7 CMRRdB = 94.5 dB 2 ⎠ ⎝ ⎛ 1 1 ⎞ − ⎟ ⎜ 1 ⎝ β oro 2REE ⎠ 1 ⎛ -3.36x10-8 ⎞ = fZ ≅ ⎜ ⎟ = 26.8 kHz 2π ⎛ 2π ⎝ -0.2 pF ⎠ CEE ⎞ ⎜ Cµ − ⎟ 2 ⎠ ⎝ g m = 40IC = 4x10−3 ro = ( ω Pdm = ) 1 = 88.4 MHz RLCµ ω Pdm = 1 = 99.0 MHz ⎛ RL ⎞ ⎜ RC ⎟Cµ 2⎠ ⎝ See the PSPICE graph in Prob. 16.84 below. 17-58 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.84 The three curves from top to bottom are: CMRR, -20log(Acm), 20log(Adm/2). frequencies (near 100 MHz), the pole of Adm approximately cancels the pole in Acm. At high 16.85 ωH = gm1 CGS1 + CGS 2 + CGD 2 (1+ gm1ro2 + gm 2 ro2 ) ⎛ 5⎞ 50V gm1 = gm 2 = 2(25x10−6 )⎜ ⎟(10−4 ) = 158 µS | ro2 ≅ = 500kΩ ⎝ 1⎠ 0.1mA CGS1 = 3pF | CGS 2 = 3pF | CGD1 = 0.5 pF | CGD 2 = 0.5 pF 1 158µS fH = = 294 kHz 2π 3pF + 3pF + 0.5 pF [1+ 2(0.158mS )500kΩ] 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-59 16.86 ωH = 50V gm1 | ID 2 = 5ID1 = 1.00mA | ro2 = = 50kΩ 1mA CGS1 + CGS 2 + CGD 2 (1+ gm1ro2 + gm 2 ro2 ) ⎛ 5⎞ ⎛ 25 ⎞ gm1 = 2(25x10−6 )⎜ ⎟(2x10−4 ) = 224 µS | gm 2 = 2(25x10−6 )⎜ ⎟(1x10−3 ) = 1.12mS ⎝ 1⎠ ⎝1⎠ CGS & CGD ∝W : CGS1 = 3pF | CGS 2 = 15 pF | CGD1 = 1pF | CGD 2 = 5 pF 1 0.224mS fH = = 99.3 kHz 2π 3pF + 15 pF + 5 pF [1+ (1.12mS + 0.224mS )50kΩ] 16.87 The most probable answer that will be produced is 60V gm1 ωH = | IC 2 ≅ 10IC1 = 1.00mA | ro2 = = 60kΩ 1.00mA Cπ 1 + Cπ 2 + Cµ 2 [1+ (gm1 + gm 2 )ro2 ] Cπ 1 = fH = 40(10−4 ) 1.2x10 9 π − 0.5 pF = 0.561pF | Cπ 2 = 40(10−3 ) 1.2x10 9 π − 0.5 pF = 10.1pF 40(10−4 ) 1 = 478 kHz 2π 0.561pF + 10.1pF + 0.5 pF [1+ 40(1.1mA)60kΩ] However, C should be approximately proportional to emitter area: Cµ 2 = 10Cµ1 = 5.00 pF | Cπ 2 = fH = 17-60 40(10−3 ) 1.2x10 9 π 40(10−4 ) − 5.00 pF = 5.10 pF 1 = 48.2 kHz 2π 0.561pF + 5.10 pF + 5.00 pF [1+ 40(1.1mA)60kΩ] ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.88 With the addition of rx, we must re-evaluate the open-circuit time constants. c µ1 r o1 c π1 g m1 v1 r x1 + v1 r x2 c µ2 + r π1 v2 r π2 - r o2 c π2 g m2 v2 - Assume: rx << ro ⎛ 1 ⎞ 1+ gm1rx 2 Cπ 2 & Cµ 2 are part of a common - emitter stage with rπo2 = rπ 2 ⎜ rx 2 + ⎟≅ gm1 ⎠ gm1 ⎝ ⎞ ⎛ ⎟ ⎜ gm1 rx1 1 ⎟ | Rπ 1o ≅ Cπ 1 : Rπ−11o = gπ 1 + gx1⎜1+ ≅ 1 ⎟ 1+ gm1rx1 gm1 ⎜ g +g + ⎟ ⎜ x1 o1 rx 2 + rπ 2 ⎠ ⎝ rx1 Cµ1 : Rµ1o = with R = ro1 (rx 2 + rπ 2 ) | Rµ1o ≅ rx1 1 1 1+ + β o gm R −1 ⎫ ⎧ 1+ gm1rx 2 rx1 ω H = ⎨Cπ 1 + Cµ1rx1 + Cπ 2 + Cµ 2 (1+ gm 2 ro2 )]⎬ [ gm1 ⎭ ⎩ 1+ gm1rx1 1 The last term will be dominant : ω H ≅ 1+ gm1rx 2 Cµ 2 (1+ gm 2 ro2 ) gm1 The most probable answer that will be generated is 50V IC 2 ≅ 4IC1 = 1.00mA | ro2 = = 50kΩ | gm 2 = 40(0.001) = 40mS 1.00mA 40(2.5x10−4 ) 40(10−3 ) Cπ 1 = − 0.3pF = 2.88 pF | C = − 0.3pF = 9.73pF π2 10 9 π 10 9 π 1 1 fH ≅ = 964 kHz 2π 1+ 0.01S (175Ω) 0.3pF [1+ 40mS (50kΩ)] 0.01S However, C should be approximately proportional to emitter area: 1 1 Cµ 2 = 4Cµ1 = 1.2 pF | f H ≅ = 241 kHz 2π 1+ 0.01S (175Ω) 1.2 pF [1+ 40mS (50kΩ)] 0.01S 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-61 16.89 ωH = gm1 | IC 2 ≅ IC1 = 100µA Cπ 1 + Cπ 2 + Cµ 2 [1+ (gm1 + gm 2 )ro2 ] 40(10−4 ) 60V ro2 = = 600kΩ | Cπ 2 = Cπ 1 = − 2 pF = 10.7 pF 100µA 10 8 π ⎤ 40(10−4 ) 1 ⎡ ⎥ = 66.2 kHz ⎢ fH = 2π ⎢⎣10.7 pF + 10.7 pF + 2 pF (1+ 2(40)(0.100mA)600kΩ)⎥⎦ 16.90 This analysis utilizes the open-circuit time-constant approach. I C3 I O + M3 REF v1 C2 gm v1 - + M2 ro M1 ix g m1 vx C1 1 gm vx - C1: C1 = CGS1 + CGS 2 | C2 = CGD 2 + CGS 3 | C1 = CGD 3 R1O : v x = (ix + gm v1 ) 1 gm | v1 = −µ f v x − v x | R1O = vx 1 = ix gm (µ f + 2) ix + ix vx - + v1 vg gm vx - + vx ro gm v1 i ro i 1 gm i ro gm1 vx C2: 17-62 1 gm i gm1 vx C3: ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 vs R2O : v x = (ix − i)ro − (gm v x − ix ) 1 gm | i = gm v x − ix 1 2ro + ⎞ ⎛ 1 v 2 gm 2v x = ix ⎜ ro + ⎟ − ro (gm v x − ix ) | R2O = x = ≅ gm ⎠ gm ix µf + 2 ⎝ R3O : v x = (ix − gm v1 )ro + R3O = ωH ≅ fH ≅ ix i − (ix + i)ro | i = ix | v1 = −2ix ro − x gm gm vx 1 = 2µ f ro + 4ro + ≅ 2(µ f + 2)ro ≅ 2µ f ro gm ix 1 1 1 ≅ = 2 2CGS CGS + CGD +2 + 2µ f roCGD 2µ f roCGD 2gm ro CGD gm µ f gm 1 2π 1 ⎛ 50 ⎞ 2 −12 2 2(2.5x10 )(2.5x10 )⎜ ⎟ (10 ) ⎝ 2.5x10−4 ⎠ −4 = 5.63 kHz −4 Note: R3O neglects any attached load resistance. If a load exists, essentially all of ix will go through the load RL, and the frequency response will significantly improve. For that case, R3O ≈ RL + ro ≈ ro. 16.91 (a) rπ = 40(15x10−6 ) 100(0.025) =167kΩ | C = 0.5 pF | C = − 0.5 pF = 0.773 pF µ π 15x10−6 2π (75x10 6 ) rπo = rπ rx = 167kΩ 500Ω = 499 Ω | gm = 40(15x10−6 )= 0.6mS | ω H = 1 rπoCT | ⎡ 430kΩ⎤ 1 = 568 kHz CT = 0.773 + 0.5 ⎢1+ 0.6mS(430kΩ) + = 561pF | f H = ⎥ ⎣ 499Ω ⎦ 2π (499)(5.61x10−10 ) (b) rπ = 40(5x10−5 ) 100(0.025) = 50.0kΩ | C = 0.5 pF | C = − 0.5 pF = 3.74 pF µ π 5x10−5 2π (75x10 6 ) rπo = rπ rx = 50kΩ 500Ω = 495 Ω | gm = 40(5x10−5 )= 2.00mS | ω H = 1 rπoCT | ⎡ 140kΩ⎤ 1 = 285 pF | f H = = 1.13 MHz CT = 3.74 + 0.5 ⎢1+ 2.0mS(140kΩ) + ⎥ ⎣ 495Ω ⎦ 2π (495)(2.85x10−10 ) 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-63 16.92 (a) Cµ = 1 pF | Cπ = 40(125x10−6 ) 2π (100x10 6 ) −1pF = 6.96 pF | rx = 500Ω | gm = 40(125x10−6 )= 5.00mS ⎡ 5.00mS(62kΩ) 62kΩ ⎤ 1 + = 1.11 MHz CT = 6.96 + 1.0 ⎢2 + ⎥ = 288 pF | f H = 0.500kΩ⎦ 2 2π (500)(2.88x10−10 ) ⎣ (b) Cπ = 40(1x10−3 ) 2π (100x10 6 ) −1pF = 62.7 pF | rx = 500Ω | gm = 40(1x10−3 )= 40.0mS ⎡ 40.0mS(7.5kΩ) 7.5kΩ ⎤ 1 + = 1.39 MHz CT = 62.7 + 1.0 ⎢2 + ⎥ = 230 pF | f H = 2 0.500kΩ⎦ 2π (500)(2.30x10−10 ) ⎣ (a) Cµ = 1 pF | Cπ = 40(100x10−6 ) 2π (100x10 6 ) 16.93 −1pF = 5.37 pF | rx = 500Ω | gm = 40(100x10−6 )= 4.00mS 100(0.25) = 25kΩ | rπo = 500Ω 25kΩ = 490Ω 10−4 1 = 2.01 MHz fH = 2π [(490Ω)(5.37 + 2)pF + (500 + 75kΩ)1pF ] rπ = (b) Cµ = 1 pF | Cπ = 40(1x10−3 ) 2π (100x10 6 ) −1pF = 62.7 pF | rx = 500Ω | gm = 40(1x10−4 )= 40.0mS 100(0.25) = 2.5kΩ | rπo = 500Ω 2.5kΩ = 417Ω 10−3 1 = 4.55 MHz fH = 2π [(417Ω)(62.7 + 2)pF + (500 + 7.5kΩ)1pF ] rπ = 17-64 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.94 For Amid , refer to Section 14.8 : RB3 = 51.8kΩ 1kΩ = 25.9kΩ, RE3 = 1.65kΩ, rπ 3 = = 500Ω 2 2 [ ( )] Avt1 = doesn' t change | RL2 = 4.7kΩ 25.9kΩ 500Ω + 81 1.65kΩ 250Ω = 3.26kΩ Avt2 = −62.8mS (3.26kΩ)= −205 | Avt3 = Av = 81(217) 500 + 81(217) = 0.972 1MΩ (−4.78)(−205)(0.972)= +943 or 59.5 dB 1.01MΩ For f L , refer to Section 16.10.5 ( ) [ )] ( R 5S = 4.7kΩ 54.2kΩ + 25.9kΩ 500Ω + 81 1.65kΩ 250Ω = 15.0kΩ 3.71kΩ + 0.5kΩ = 300Ω 81 ⎞ 1 ⎛ 1 1 ⎜99 + 319 + 372 + 2340 + ⎟ = 533 Hz fL = + 2π ⎜⎝ 15.0kΩ(1µF ) 300Ω(22µF )⎟⎠ Rth3 = 25.9kΩ 4.7Ω 54.2kΩ = 3.71kΩ | R6S = 250 + 1.65kΩ For f H , refer to Section 16.10.5 [ )] ( R L2 = 54.2kΩ 4.7kΩ 25.9kΩ 500Ω + 81 1.65kΩ 250Ω = 3.07kΩ ⎡ ⎛ 3.07kΩ ⎞⎤ −7 Rπo2CT 2 = (610Ω) ⎢39 pF + 1pF ⎜1+ 67.8mS (3.07kΩ)+ ⎟⎥ = 1.54x10 s 0.610kΩ ⎝ ⎠⎦ ⎣ C π + Cµ = gm ωT ∝ IC → Cπ 3 = 2(51pF )−1pF = 101pF | Rth3 = 25.9kΩ 4.7Ω 54.2kΩ = 3.71kΩ 3.71kΩ + 250Ω 101pF + (3.71kΩ + 250Ω)1pF = 1.52x10−8 s 1+ 159.4mS (0.217kΩ) fH = ( 1 2π 1.07x10 s + 1.54x10−7 s + 1.52x10−8 s 03/09/2007 −7 ) = 576 kHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-65 16.95 For Amid , refer to Section 14.8 : R1 = 39kΩ, R2 = 11kΩ, RE21 = 750Ω, RC 2 = 2.35kΩ 2.39kΩ rπ 2 = = 1.40kΩ | RI1 = 620Ω 39kΩ 11kΩ = 578Ω | Avt1 = −10mS 578Ω 1.20Ω = −3.91 2 RI 2 = 2.35Ω 51.8kΩ = 2.25kΩ | Avt2 = −62.8mS 2.25kΩ 19.8kΩ = −127 | Avt3 doesn't change ( ( Av = ) ) 1MΩ (−3.91)(−127)(0.95)= +467 or 53.4 dB 1.01MΩ For f L , refer to Section 16.10.5 ⎛17.2kΩ 2.39kΩ ⎞ 17.2kΩ R3S = 620Ω 12.2kΩ + ⎜ 620Ω 12.2kΩ = 552Ω ⎟ = 1.64kΩ | Rth = 2 ⎠ 2 ⎝ 2 ⎛R r ⎞ 552 + 1195 R4S = 750 = 11.4Ω | R5S = ⎜ C2 o2 ⎟ + RB 3 Rin3 = 16.3kΩ 151 ⎝ 2 2⎠ ( ) ( Rth3 = 51.8kΩ 2.35Ω 27.1kΩ = 2.08kΩ | R6S = 250 + 3.3kΩ fL = ) 2.08kΩ + 1.00kΩ = 288Ω 81 1 (99 + 319 + 610 + 3987 + 61.4 + 158)= 833 Hz 2π For f H , refer to Section 16.10.5 RL1 = 598Ω ⎡ ⎛ 2.39kΩ 399Ω ⎞⎤ −8 = 399Ω | RthCT1 = (9.9kΩ) ⎢5 pF + 1pF ⎜1+ 0.01S (399Ω)+ ⎟⎥ = 9.92x10 s 2 9900Ω ⎠⎦ ⎝ ⎣ Rth2 = 598Ω 12.2kΩ 2.39kΩ = 544Ω | rπo2 = R4S = (544Ω + 250Ω)= 596Ω 2 2 RL2 = 51.8kΩ Cπ + Cµ = gm ωT 4.7kΩ Rin2 = 2.25kΩ 19.8kΩ = 2.02kΩ 2 ∝ IC → Cπ 2 = 2(40 pF )−1pF = 79 pF ⎡ ⎛ 2.02kΩ ⎞⎤ −7 rπo2CT 2 = (544)⎢79 pF + 1pF ⎜1+ 136mS (2.02kΩ)+ ⎟⎥ = 1.95x10 s 0.544kΩ ⎠ ⎝ ⎣ ⎦ Rth3 = 54.2kΩ 4.7kΩ 51.8kΩ = 2.08kΩ 2 2 2.08kΩ + 250Ω 50 pF + (2.08kΩ + 250Ω)1pF = 8.31x10−9 s 1+ 79.6mS (0.232k ) fH = ( 1 2π 9.92x10 s + 1.95x10−7 s + 8.31x10−9 s 17-66 −8 ) = 526 kHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.96 fo = gm = 1 1 = = 22.5 MHz −5 2π LCGD 2π 10 (5x10−12 ) 2ID 0.02 = = 0.01S 2 VGS − VTN 1 + 10 ro = 0.0167 = 6.99kΩ 0.01 Av = −gm (ro RL ) = −0.01S(6.99kΩ 10kΩ) = −41.1 BW = 1 1 22.5 = = 7.75 MHz Q = = 2.90 2πRP CGD 2π (4.11kΩ)(5 pF ) 7.75 16.97 (a) f o = (b) ro = 1 2π (C + C )L µ →C = 1 1 − Cµ = − 2 pF = 20.1pF 2 2 (2πf o ) L 2π (10.7x10 6 Hz) 10−5 H [ ] 75V + 10V 1 10.7 = 8.50kΩ | BW = = 847kHz | Q = = 12.6 10mA 2π (8.5kΩ)(22.1pF ) 0.847 (c ) Q = 100 | BW = fo 1 1 = 107kHz | ro = = = 67.3kΩ Q ω o (C + Cµ ) 2π (107kHz)(22.1pF ) 67.3kΩ = 7.918 | n = 2.81 8.50kΩ C 2 pF = 0.253pF | C = 22.1− 0.253 = 21.9 pF (d ) Cµ' = µ2 = 7.918 n n2 = 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-67 16.98 220 pF VC C 6 µH D 20(220) 20 pF 20 pF (a) CD = = 20 pF | C = pF = 18.3pF 20 + 220 VC 0 1+ 1+ 0.9 0.9 1 1 = = 15.2MHz fo = 2π LC 2π (6µH )(18.3pF ) CD = 5.75(220) 20 pF = 5.75 pF | C = pF = 5.60 pF 5.75 + 220 10 1+ 0.9 1 1 = = 27.5MHz fo = 2π LC 2π (6µH )(5.60 pF ) (b) CD = 17-68 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.99(a) 4 C1 C2 1 pF 1 rπ 5 pF + v RL - gm v 5 µΗ 20 pF R EQ 20 pF C EQ C EQ n 2 R EQ n2 8.24 pF 3.33 kΩ CEQ = Cπ + Cµ [1+ gm RL ] = 5 pF + 1pF [1+ 40(1mA)(5kΩ)] = 206 pF CP = 20 pF + REQ = rπ CEQ 206 pF = 20 pF + = 28.2 pF | f o = 2 52 n 2π RL (1+ gm RL )(ωRL Cµ ) 2 = 2.5kΩ 1 = 13.4 MHz (5µH )(28.2 pF ) 5000 (1+ 200)[2π (13.4 MHz)(5kΩ)(1pF )] 2 =2.5kΩ 140Ω =133Ω 1 13.4 = 1.70 MHz | Q = = 7.88 2π (3.33kΩ)(28.2 pF ) 1.70 Note the huge error that would be caused by using only rπ as the input resistance term. RP = n 2 REQ = 25(133Ω) = 3.33kΩ | BW = 20 pF vs 2 CA v1 SC A vs 2 n 2 R EQ 20 pF 5 µH C EQ n2 ⎛ 1⎞ v1 = j2π (13.4 MHz)(20 pF )⎜ ⎟(3.33kΩ)v i = j2.80v s ⎝ 2⎠ j2.80v s v o = (−gm RL ) = −40(10−3 )(5kΩ) j0.560v i | Av = 112∠ − 90 o 5 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-69 + j 2.80 vs 5 v RL gm v - 16.99(b) 10 pF R EQ 10 pF C EQ RL v 5 µH vs + 133 Ω 206 pF gm v - CT = 5 pF + 1pF [1+ 40(1mA)(5kΩ)] = 206 pF | CP = 20 pF + 206 pF = 226 pF fo = 1 2π REQ = rπ (5µH )(226 pF ) = 4.74 MHz RL (1+ gm RL )(ωRL Cµ ) 2 = 2.5kΩ REQ = 2.5kΩ 1.12kΩ =774Ω | BW = 5000 (1+ 200)[2π (4.74 MHz)(5kΩ)(1pF )] 2 1 4.74 = 910 kHz | Q = = 5.21 2π (774Ω)(226 pF ) 0.910 v o = j2π (4.74 MHz)(10 pF )(774Ω)(−gm RL )v i v o = j2π (4.74 MHz)(10 pF )(774Ω)[−0.04mS(5kΩ)]v i | Av = 46.1∠ − 90 o 17-70 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.100 (a) Referring to Eqns. (16.180-16.182) in Jaeger and Blalock, 1 1 = = 10.1 MHz fo = 2π L(CGD + C ) 2π (10µH )(25 pF ) ro ≅ 1 1 = = 2500Ω λID (0.02 /V )(20mA) BW = Q= gm ≅ 2K n ID = 2(0.005)(0.02 = 14.1 mS 1 1 = = 2.55 MHz 2π (ro )(CGD + C ) 2π (2.5kΩ)(25 pF ) 10.1 = 3.96 | Amid = −gm ro = −µ f = −35.4 2.55 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-71 16.100(b) V1 C CGD r V CGS S o C + 2 VO 1 L g V m - S ⎡(sCGD − gm )Vs⎤ ⎡s(C1 + CGD + C2 ) + go ⎢ ⎥=⎢ −sC2 0 ⎣ ⎦ ⎢⎣ −sC2 ⎤⎡V ⎤ jωC2 ( jωCGD − gm ) V 1 1 ⎥⎢ ⎥ | AV ( jω ) = o = sC2 + ⎥⎣Vo ⎦ Vs ∆ sL ⎦ Let CEQ = C1 + CGD ⎡ C + C2 1 ⎤ g go ∆ (s) = CEQ C2 ⎢s2 + s o + + EQ ⎥ CEQ sCEQ C2 L CEQ C2 L ⎦ ⎣ ⎡ C + C2 1 ⎤ CEQ + C2 1 g go ∆ ( jω ) = CEQ C2 ⎢ EQ − ω 2 + jω o + ⎥ | ω o2 = CEQ jωCEQ C2 L ⎦ CEQ C2 L ⎣ CEQ C2 L g C ω o m − jω o2 GD CEQ CEQ C ⎞ gm ro ⎛ Av ( jω o ) = − =− 1− jω o GD ⎟ ⎜ g go 1 ⎝ gm ⎠ ωo o − 1− 2 CEQ ω oCEQ C2 L ω o LC2 µf Av ( jω o ) = − 1− But ω1 = CEQ CEQ + C2 ⎛ ⎛ CEQ ⎞⎛ ω ⎞ ω ⎞ ⎟⎜1− j o ⎟ ⎜1− j o ⎟ = −µ f ⎜1+ ω1 ⎠ C2 ⎠⎝ ω1 ⎠ ⎝ ⎝ ⎛ C ⎞ gm > ωT . So, Av ( jω o ) ≅ −µ f ⎜1+ EQ ⎟ for ω1 << ωT CGD C2 ⎠ ⎝ Referring to Eqs. (17.192 -17.193) : BW = ωo Q = go g 1 ⎛ 1 ⎞ − 2 o = ⎟= ⎜1− 2 CEQ ω o CEQ C2 L roCEQ ⎝ ω o LC2 ⎠ 1 ⎛ C ⎞ roCEQ ⎜1+ EQ ⎟ C2 ⎠ ⎝ ⎛ C ⎞ Q = ω o roCEQ ⎜1+ EQ ⎟ C2 ⎠ ⎝ 17-72 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 C2CEQ 45(40) = pF = 21.2 pF | f o = CEQ + C2 45 + 40 2π ro ≅ 1 (10µH )(21.2 pF ) = 10.9MHz ⎛ 45 ⎞ 1 = 2.50kΩ | Q = 2π (10.9MHz)(2.50kΩ)(45 pF )⎜1+ ⎟ = 16.4 ⎝ 40 ⎠ 0.02(20mA) 10.9MHz = 666 kHz 16.4 ⎛ C ⎞ ⎛ 45 pF ⎞ = −µ f ⎜1+ EQ ⎟ = − 2(0.005)(0.02)(2500)⎜1+ ⎟ = −75.1 C2 ⎠ ⎝ 40 pF ⎠ ⎝ BW = Amid ⎛ 1 ⎞ g ⎛ 1 ⎞ 2(0.005)(0.02) Checking the approximation : ⎜ ⎟ m = ⎜ ⎟ = 450 MHz >> ω o ⎝ 2π ⎠ CGD ⎝ 2π ⎠ 5 pF 16.101 CEQ = fo = (C1 + 5 pF )C2 C1 + 5 pF + C2 1 2π = 25 pF | C2 = 50 pF | C1 = 45 pF (10µH )(25 pF ) = 10.1 MHz | ro = Using the results from Prob. 17.113: BW = Q= 10.1 = 15.9 | Amid 0.635 03/09/2007 1 = 2.50kΩ 0.02(20mA) 1 = 635 kHz ⎛ 50 pF ⎞ 2π (2.50kΩ)(50 pF )⎜1+ ⎟ ⎝ 50 pF ⎠ ⎛ C ⎞ ⎛ 50 pF ⎞ = −µ f ⎜1+ 1 ⎟ = − 2(0.005)(0.02)(2500)⎜1+ ⎟ = −70.7 ⎝ 50 pF ⎠ ⎝ C2 ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-73 16.102 *Problem 16.102(a) - Fig. P16.100(a) VS 1 0 AC 1 CGD 1 2 5PF GM 2 0 1 0 14.1MS RO 2 0 2.5K C1 2 0 20PF L1 2 0 10UH .AC LIN 400 8MEG 12MEG .PRINT AC VM(2) VP(2) .PROBE V(2) .END Results: Amid = 35.3, fo = 10.1 MHz, BW = 2.50 MHz *Problem 16.102(b) - Fig. P16.100(b) VS 1 0 AC 1 CGD 1 2 5PF GM 2 0 1 0 14.1MS RO 2 0 2.5K C1 2 0 40PF C2 2 3 40PF L1 3 0 10UH .AC LIN 400 8MEG 12MEG .PRINT AC VM(2) VP(2) VM(3) VP(3) .PROBE V(2) V(3) .END Results: Amid = 75.1, fo = 10.1 MHz, BW = 670 kHz *Problem 16.102(c) - Problem 16.101 VS 1 0 AC 1 CGD 1 2 5PF GM 2 0 1 0 14.1MS RO 2 0 2.5K C1 2 0 45PF C2 2 3 50PF L1 3 0 10UH .AC LIN 400 8MEG 12MEG .PRINT AC VM(2) VP(2) VM(3) VP(3) .PROBE V(2) V(3) .END Results: Amid = 70.7, fo = 10.1 MHz, BW = 640 kHz 17-74 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 16.103 ⎛ g ⎞ a C ≅ C + C 1+ g R = C + C ⎜ ( ) EQ GS1 GD1( m1 L ) GS1 GD1⎝1+ g m1 ⎟⎠ m2 I D2 = I D1 = 2(0.005) 2 0.01 0 − (−1) = 5.00mA | VGS 2 = −4 + = −3V 0.01 2 [ ] VDS1 = VSG2 = +3V > 1V → Saturation region is ok. | g m2 = g m1 = 2(0.01)(0.005) = 10.0mS CEQ = 20 pF + 5 pF [1+ 1]= 30 pF | CP = C1 + C3 + CEQ = 20 pF + 20 pF + 30 pF = 70 pF Require C2 + CGD = CP → C2 = 70 pF − 5 pF = 65 pF (b) f o = RP = RG 1 2π LCP (1+ g = 1 2π (10µH )(70 pF ) RL1 RL1 )(ωRL1CGD1 ) 2 m1 = 100kΩ RP = 100kΩ 140kΩ =58.3kΩ | BW1 = = 6.02 MHz | RL1 = 1 g m2 100 (1+ 1)[2π (6.02 MHz)(100)(5 pF )] 2 1 1 = = 39.0kHz 2πRP CP 2π (58.3kΩ)(70 pF ) 1 2 BW2 ≅ BW1 2 −1 = 25.1kHz | Note that this is an approximation since R P = 100kΩ 6.02 MHz = 240 | vo = (ωC3vi )(RP )(−g m RD ) 25.1kHz = 2π (6.02 MHz)(20 pF )(58.3kΩ)(−10.0mS )(100kΩ)= 4.41x10 4 at the output and 58.3 kΩ at the input. | Q = Amid 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-75 16.104 *Problem 16.103 - Synchronously-Tuned Cascode Amplifier VDD 5 0 DC 12 VS 1 0 AC 1 C3 1 2 20PF L1 2 0 10UH C1 2 0 20PF RG 2 0 100K M1 3 2 0 0 NFET1 CGS1 2 0 20PF CGD1 2 3 5PF M2 4 0 3 3 NFET2 CGS2 3 0 20PF CGD2 4 3 5PF L2 4 5 10UH C2 4 5 65PF RD 4 5 100K .MODEL NFET1 NMOS VTO=-1 KP=10M .MODEL NFET2 NMOS VTO=-4 KP=10M .OP .AC LIN 200 5.5MEG 6.5MEG .PRINT AC VM(2) VP(2) VM(3) VP(3) VM(4) VP(4) .PROBE .END Results: Amid = 279, fo = 6.10 MHz, Q = 24 The amplifier is actually stagger-tuned. Note that the loop of capacitors around M1 messes up the hand results based upon the CEQ approximation. The CEQ approximation itself may not be accurate enough for precise synchronous tuning. Plot a graph of V(2) and V(3) to show the problem. Evidence of the problem is also provided by the huge error in the mid-band gain. 16.105 From Prob. 16.103 : CP 2 = 1 (2πf o ) L 2 = 1 2 ⎛ ⎞ 1.02 ⎜ 2π ⎟L ⎜ LCP1 ⎟⎠ ⎝ = CP1 (1.02) 2 = 70 pF (1.02) 2 = 67.3 pF C2 = CP2 − CGD2 = 67.3 pF − 5 pF = 62.3 pF | R p2 = 100kΩ BW1 = 1 1 = 39.0kHz | BW2 = = 23.7kHz 5 2π (58.3kΩ)(70 pF ) 2π 10 Ω (67.3 pF ) ( ) BW2 39.0kHz 23.7kHz BW1 + 0.02 f o1 + = + 0.02(6.02 MHz)+ = 152kHz 2 2 2 2 f + 1.02 f o 6.08 MHz = 6.08 MHz | Q = = 40 The new f o ≅ o1 2 152kHz BW ≅ 16.106 17-76 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 *Problem 16.105 - Stagger-Tuned Cascode Amplifier VDD 5 0 DC 12 VS 1 0 AC 1 C3 1 2 20PF L1 2 0 10UH C1 2 0 20PF RG 2 0 100K M1 3 2 0 0 NFET1 CGS1 2 0 20PF CGD1 2 3 5PF M2 4 0 3 3 NFET2 CGS2 3 0 20PF CGD2 4 3 5PF L2 4 5 10UH C2 4 5 62.3PF RD 4 5 100K .MODEL NFET1 NMOS VTO=-1 KP=10M .MODEL NFET2 NMOS VTO=-4 KP=10M .OP .AC LIN 200 5.5MEG 6.5MEG .PRINT AC VM(2) VP(2) VM(3) VP(3) VM(4) VP(4) .PROBE .END Results: Amid = 512, fo = 6.19 MHz, BW = 0.19 MHz, Q = 33 16.107 + Yin C µ v r π C - π Yin = gπ + sCπ + Y1 | I = sCµ (V − Vo ) = sCµ Y1 ( jω ) = jωCµ RL gm v (sC µ + Y1 C µ v RL - − gm )V = (sCµ + GL )Vo | Vo = gm v (sC (sC µ µ − gm ) V + GL ) gm + GL g + GL 1+ gm RL I V | Y1 = = sCµ m = sCµ V (sCµ + GL ) (sCµ + GL ) (sCµ RL + 1) 1− jωCµ RL 2 1+ gm RL = jωCµ (1+ gm RL ) | For (ωCµ RL ) << 1, 2 (jωCµ RL + 1) (ωCµ RL ) + 1 Y1 ( jω ) ≅ jωCµ (1+ gm RL ) + (1+ gm RL ) ωC RL ( RL ) 2 µ From the results we see that the input capacitance is correctly modeled by the total Miller input capacitance, but the input resistance is not correctly modeled by just rπ: 03/09/2007 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-77 RL Cin = Cπ + Cµ (1+ gm RL ) | Rin = rπ (1+ gm RL )(ωCµ RL ) 2 (b) Cin = CGS + CGD (1+ gm RL ) = 6 pF + 2 pF [1+ 5mS (10kΩ)] = 108 pF Rin = RL (1+ gm RL )(ωCGD RL ) 2 Note also that X C in = = 10kΩ [1+ 5mS(10kΩ)][2π (5x10 6 )(2 pF )(10kΩ)] 2 1 2π (5x10 )(108 pF ) 6 = 497Ω ! = 295 Ω | Both values are far less than infinity. Although the CT approximation gives an excellent estimate for the dominant pole of the common-emitter amplifier, it does not do a good job of representing the input admittance at high frequencies. An improved estimate is needed for several of the problems to come. + Yin C µ v r π C π - Yin = gπ + sCπ + Y1 | I = sCµ (V − Vo ) = sCµ Y1 ( jω ) = jωCµ + RL Y1 gm v (sC µ C µ v RL - − gm )V = (sCµ + GL )Vo | Vo = gm v (sC (sC µ µ − gm ) V + GL ) gm + GL g + GL 1+ gm RL I V | Y1 = = sCµ m = sCµ V (sCµ + GL ) (sCµ + GL ) (sCµ RL + 1) 1− jωCµ RL 2 1+ gm RL = jωCµ (1+ gm RL ) | For (ωCµ RL ) << 1, 2 (jωCµ RL + 1) (ωCµ RL ) + 1 Y1 ( jω ) ≅ jωCµ (1+ gm RL ) + (1+ gm RL ) ωC RL ( RL ) 2 µ From the results we see that the input capacitance is correctly modeled by the total Miller input capacitance, but the input resistance is not correctly modeled by just rπ: Cin = Cπ + Cµ (1+ gm RL ) | Rin = rπ 17-78 RL (1+ gm RL )(ωCµ RL ) 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 CHAPTER 17 17.1 (a) T = Aβ = ∞ (b) A = 10 80 20 1 Av = | β =5 FGE = 0 | = 10000 | T = 10000(0.2)= 2000 A 10000 100% 100% = = 5.00 | FGE = = = 0.05% 1+ Aβ 1+ 2000 1+ Aβ 2001 A 10 100% (c) T = 10(0.2)= 2 | Av = 1+ Aβ = 1+ 2 = 3.33 | FGE = 1+ 2 = 33.3% Av = 17.2 (a) β = R + R R1 1 1kΩ 1 = 101kΩ 101 = 2 (b) T = Aβ = 10 86 20 ⎛ 1 ⎞ A 2x10 4 = = 100 ⎜ ⎟ = 198.6 | Av = 1+ Aβ 200 ⎝ 101⎠ 17.3 80 ⎛ 1 ⎞ R1 1kΩ 1 = = | T (s) = Aβ = 10 20 ⎜ ⎟ = 99.0 ⎝ 101⎠ R1 + R2 101kΩ 101 ⎛100kΩ ⎞⎛ 99 ⎞ R Aβ Av = − 2 = −⎜ ⎟⎜ ⎟ = −99 ⎝ 1kΩ ⎠⎝ 100 ⎠ R1 1+ Aβ (a) β (s) = 17.4 β (s)= Z1 (s) Z1 (s)+ Z2 (s) = R R+ 1 sC s = s+ 1 RC 80 = s | A = 10 20 = 10 4 s + 5000 10 4 s ⎛ 1 ⎞ s + 5000 ⎛ 1 ⎞⎛ 1 ⎞ 10 s Z Aβ T (s)= Aβ = | Av = − 2 = −⎜ = −⎜ ⎟ ⎟⎜ ⎟ 4 s + 5000 Z1 1+ Aβ 10 s ⎝ sRC ⎠ ⎝ RC ⎠⎝ s + 0.5 ⎠ 1+ s + 5000 Instead of a pole at the origin, the integrator has a low - pass response with a pole a ω = 0.5 rad/s. 4 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-1 17.5 AV = A A 1 1 = | From Chapter 12, GE = = 1+ Aβ 1+ A 1+ Aβ 1+ A 1 ≤ 10−4 → A ≥ 9999 | A ≥ 80 dB 1+ A 17.6 2.0V Output Voltage 0V No feedback Feedback -2.0V -2.0V -1.0V 0V VS Input 1.0V 2.0V Voltage *Problem 17.6 – Figure P17.6- Class-B Amplifiers VCC 3 0 DC 10 VEE 4 0 DC -10 VI 1 0 DC 0 Q1 3 1 2 NBJT Q2 4 1 2 PBJT RL1 2 0 2K RID 1 7 100K E1 5 0 1 7 5000 RO 5 6 100 Q3 3 6 7 NBJT Q4 4 6 7 PBJT RL2 7 0 2K .MODEL NBJT NPN .MODEL PBJT PNP .OP .DC VS -10 10 .01 .PROBE V(1) V(2) V(7) .END 17.7 1 1 ≅ 1+ Aβ Aβ 1 200 200 = 200 | GE ≅ ≤ 0.002 → A ≥ = 105 | A ≥ 100 dB β A 0.002 Av = A 1+ Aβ | From Chapter 12, GE = 17.8 17-2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 SAA v = A ∂A v Av ∂A Av = A 1+ Aβ ∂A v (1+ Aβ )1− Aβ 1 = = 2 2 ∂A (1+ Aβ ) (1+ Aβ ) SAA v = ∂A v Av 1 1+ 10 (0.01) 5 = SAA v ∂A A = = SAA v = 1 A 1 1 = ≈ 2 A 1+ Aβ ( ) 1+ Aβ Aβ 1+ Aβ 1 1001 1 10% = 9.99x10−3% 1001 17.9 (a) Series-series feedback (b) Shunt-series feedback (c) Shunt-shunt feedback (d) Series-shunt feedback 17.10 (a) Series-shunt feedback (b) Shunt-series feedback (c) Series-series feedback (d) Shunt-shunt feedback 17.11 (a) Shunt-series and series-series feedback (b) Shunt-shunt and series-shunt feedback 17.12 (a) Series-shunt and series-series feedback (b) Shunt-series and shunt-shunt and feedback 17.13 86 20 20000 io | io = ii (40kΩ) → Ai = 8.00 x 10 5 ii 1kΩ With resistive feedback, the closed - loop gain cannot exceed the open - loop gain. (a) Av = 10 = 20000 | Ai = Therefore, Ai ≤ 8.00 x 10 5. (b) Atr = io io Ai 8x10 5 = = | Atr ≤ = 20 S v i ii (40kΩ) (40kΩ) 4 x10 4 Ω ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-3 17.14 90 A = 10 20 = 31600 (a) R = Rid (1+ Aβ ) | For β = 1, Rin = 40kΩ(1+ 31600) = 1.26 GΩ (b) R in = (c) R out = Ro (1+ Aβ ) | For β = 1, Rout = 1kΩ(1+ 31600)= 31.6 MΩ in (d ) R out Rid 40kΩ | For β = 1, Rin = = 1.27 Ω (1+ Aβ ) (1+ 31600) = Ro 1kΩ | For β = 1, Rout = = 31.6 mΩ (1+ Aβ ) (1+ 31600) 17.15 The circuit topology is identical to Fig. 17.8. h11F = 5kΩ 45kΩ = 4.50kΩ | h22F = (45kΩ + 5kΩ) = (50.0kΩ) -1 β = h12F = v1 v2 = i2 = 0 5kΩ 1 = 5kΩ + 45kΩ 10 | RL -1 1 = 5kΩ 50kΩ = 4.55kΩ h22F 4.55kΩ 20kΩ 4000) = 2570 ( 1kΩ + 4.55kΩ 1kΩ + 20kΩ + 4.5kΩ A 2570 2570 = = = 9.96 Av = ⎛ ⎞ 1 + Aβ 258 1 1 + 2570⎜ ⎟ ⎝10 ⎠ A= Rin = RinA (1 + Aβ )= (1kΩ + 20kΩ + 4.5kΩ)(258)= 6.58 MΩ Rout = 17-4 A 5kΩ 50kΩ 1kΩ Rout = = 3.18 Ω 1 + Aβ 258 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.16 (a) + A RI + RL v o vI R 2 R1 Feedback Network (b) h A 11 = i2 i1 h21A = (c) A = v 2 =0 -1 i 1 =0 =− -1 20kΩ(4000) 1kΩ v 2 =0 v1 v2 h12A = = 15kΩ | h11F = 4.3kΩ 39kΩ = 3.87kΩ | h11T = 18.9kΩ = (1kΩ) = (1kΩ) i2 v2 h22A = v1 i1 = 0 | h12F = i 1 =0 v1 v2 −h21A (R + h )(h I T 11 T 22 + GL ) | h22F = (39kΩ + 4.3kΩ) = (43.3kΩ) -1 = −80,000 | h21F = = i 2 =0 = i2 i1 =− v 2 =0 -1 | h22T = +1.02mS 4.3kΩ = −0.0993 39kΩ + 4.3kΩ 4.3kΩ = 0.0993 39kΩ + 4.3kΩ −(−80000) = 2680 ⎛ 1 1 1 ⎞ (1kΩ + 20kΩ + 3.87kΩ)⎜⎝ 5.6kΩ + 1kΩ + 43.3kΩ ⎟⎠ β = 0.0993 (d ) Av = (e) h A 21 2680 = 10.0 1+ 2680(0.0993) >> h21F | h12F >> h12A | Note : (R in = 6.64 MΩ, Rout = 3.11 Ω) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-5 17.17 + + A v v o _ S R 2 R 1 1k Ω + vs 40 k Ω v1 1kΩ 8.5 k Ω - v1 i1 v 2=0 v1 v2 = i2 = 0 o _ 316v 1 F = 1kΩ 7.5kΩ = 882Ω | h22 = β = h12F = + v 882 Ω h11F = R2 7.5 k Ω R1 i2 v2 = i1 = 0 1 1 = 1kΩ + 7.5kΩ 8.5kΩ 1kΩ 1 = 1kΩ + 7.5kΩ 8.5 100(.025V ) 100 = 12.6kΩ (200µA) =198µA | rπ = 198µA 101 v 40kΩ (β o + 1)8.5kΩ (101)8.5kΩ A= o = = 309 = 304 (316) v s 40kΩ + 0.882kΩ RO + rπ + (β o + 1)8.5kΩ 1kΩ + 12.6kΩ + (101)8.5kΩ IC = α F IE = Av = A = 1+ T 304 304 = = 8.27 ⎛ 1 ⎞ 36.8 1+ 304⎜ ⎟ ⎝ 8.5 ⎠ Rin = RinA (1+ T ) = 40.9kΩ(36.8) = 1.51 MΩ | Rout = 17-6 A out R = 1+ T 8.5kΩ 12.6kΩ + 1kΩ 101 = 3.60 Ω 36.8 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.18 + + vO _ v ref R R v ref A-Circuit v h11F = 1 i1 v =0 2=0 ( i F | h22 = 2 v2 1 = R i =0 1 =1 i2 = 0 (β o + 1)R = g m1 (ro2 π 5 + (β o + 1)R )r A = gm1 ro2 ro4 [rπ 5 + (β o + 1)R] v | h12F = 1 v2 ro2 ro4 (β o + 1)R ro4 )+ rπ 5 + (β o + 1)R 50 + 1.4 50 + 11.3 = 514kΩ | ro4 = = 613kΩ | ro2 ro4 = 280kΩ −4 10 10−4 100(.025) 12 IC 5 ≅ IE 5 ≅ 4 = 1.2mA | rπ 5 = = 2.08kΩ 10 1.2mA (101)10kΩ = 876 A = 40(10−4 )(280kΩ) 280kΩ + 2.08kΩ + (101)10kΩ ro2 = A 876 109 = = = 0.999 1+ T 1+ 876(1) 110 100(0.025) Rin = Rid (1+ T ) = 2rπ 1 (1+ T ) = 2 (877) = 43.9 MΩ 10−4 r +r r R π 5 o2 o4 10kΩ 2.08kΩ + 280kΩ βo + 1 101 Rout = = = 2.49 Ω 1+ T 877 io 100 ⎛ 1 ⎞ v α v io = α oie = α o o | = o o = ⎟(0.999) = 98.9 µS ⎜ R v ref R v ref 101 ⎝10 4 ⎠ Av = ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-7 17.19 + RI A 1 kΩ + vo - vI R2 91 k Ω R1 10 k Ω RL 2 kΩ Feedback Network h11F = v1 i1 v = 10kΩ 91kΩ = 9.01kΩ | h22F = 2 =0 β = h12F = A= = i2 = 0 = i1 = 0 1 2kΩ (1kΩ + 7.5kΩ) = 1 1.96kΩ 10kΩ 1 = 10kΩ + 91kΩ 0.0990 ( ) vo 25kΩ 1.96kΩ = 10 4 = 4730 1kΩ + 1.96kΩ vi 1kΩ + 25kΩ + 9.01kΩ Av = A 4730 = = 10.1 | Rin = RinA (1+ T ) = 34.0kΩ(469) = 16.0 MΩ 1+ Aβ 1+ 4730(0.990) Rout = 17-8 v1 v2 i2 v2 A 1.96kΩ 1kΩ Rout = = 1.41 Ω 1+ T 469 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.20 (a) S (b) = R in A ∂Rin =S Rin (c) S R out A = S AR out = − (d) ∂Rout Rout A ∂Rin A Aβ | Rin = RinA (1+ Aβ ) | S AR in = A RinAβ = ≈1 Rin ∂A Rin (1+ Aβ ) (1+ Aβ ) R in A ∂A A = A ∂Rout Rout ∂A 5x10 4 (0.01) 10% = 9.98% 1+ 5x10 4 (0.01) | Rout = A A Rout ∂Rout βRout | =− (1+ Aβ ) ∂A (1+ Aβ )2 A A(1+ Aβ ) βRout Aβ =− ≅ −1 2 A Rout 1+ A β ( ) 1+ A β ( ) =S R out A ∂A A =− 105 (0.01) 10% = −9.99% 1+ 105 (0.01) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-9 17.21 + i v1 i 100 k Ω 36 k Ω 1kΩ + 4000 v - 20 k Ω 5kΩ 1 36 k Ω 36 k Ω i1 v1 v y11F = = 2 =0 1 36kΩ | y22F = i2 v2 = v1 = 0 1 36kΩ | y12F = i1 v2 (20kΩ 36kΩ 100kΩ)= 11.4kΩ | (5kΩ 36kΩ)= 4.39kΩ A= =− v1 = 0 1 36kΩ vo 4.39kΩ = −4000 (11.4kΩ)= −3.71x107 1kΩ + 4.39kΩ ii Atr = Rin = A = 1+ Aβ −3.71x10 7 = −36.0 kΩ ⎛ 1 ⎞ 7 1+ −3.71x10 ⎜− ⎟ ⎝ 36x103 ⎠ ( ) (20kΩ 36kΩ 100kΩ) ⎛ 1 ⎞ 1+ −3.71x10 ⎜ − ⎟ ⎝ 36x103 ⎠ 17-10 ( 7 ) = 11.1 Ω | Rout = (36kΩ 5kΩ 1kΩ) ⎛ 1 ⎞ 1+ −3.71x10 ⎜ − ⎟ ⎝ 36x103 ⎠ ( 7 ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 = 0.790 Ω 17.22 A + + RL RI iI vo 10 k Ω 100 k Ω RF 10 k Ω Feedback Network y11A = y11F = i1 v1 v = 2 =0 i1 v1 v = 2 =0 1 20kΩ | y22A = 1 10kΩ | y22F = i2 v2 i2 v2 = v1 =0 = v1 =0 1 1kΩ | y21A = 1 10kΩ i2 v1 v | y12F = =− (−4000) = 4S 2 =0 i1 v2 =− v1 =0 1kΩ 1 10kΩ | y12A = | y21F = i2 v1 v i1 v2 =0 v1 =0 =− 2 =0 1 10kΩ 1 1 1 1 T + = 0.150mS | y22 = + = 1.10mS 20kΩ 10kΩ 1kΩ 10kΩ − y21A −4 A= = = −2.08x10 7 Ω | β = y12F = −10−4 −5 −3 −3 −4 T T 10 + 0.150x10 1.1x10 + 10 GI + y11 y22 + GL y11T = ( Atr = )( ) ( )( ) A −2.08x10 Ω = = −10.0 kΩ | Aβ = 2080 1+ Aβ 1+ −2.08x10 7 Ω −10−4 S Note : Rin = 7 ( )( 100kΩ 10kΩ 20kΩ 1+ 2080 ) = 1.92 Ω | Rout = 10kΩ 1kΩ 10kΩ 1+ 2080 = 0.400 Ω ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-11 17.23 +12 V 500 µA Q Q2 1kΩ Q Q 2 4.7 k Ω 1 1 v i 36 k Ω 36 k Ω 1kΩ 1k Ω IC1 = 500µA − IB 2 | IE 2 = IB1 + IC1 = 500µA − IE 2 = 37 37IB1 + 700µA 101 36000IB1 + 0.7 I = 37IB1 + 700µA | IB 2 = E 2 1000 101 = 493µA − 0.366IB1 → IC1 = 491.2µA IC1 100 + 700µA = 881.7µA | IC 2 = IE 2 = 873µA 100 101 Q Q i 1 2 1k Ω 36 k Ω i 0.001v 1kΩ 36 k Ω i R EQ 17-12 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 4.7k Ω i1 v1 v y11F = rπ 1 = = 2=0 1 36kΩ F | y 22 = i2 v2 = v1 = 0 1 36kΩ 1kΩ | y12F = i1 v2 =− v1 = 0 1 36kΩ 100(0.025) 100(0.025) 50 + 1.6 = 5.09kΩ | rπ 2 = = 2.86kΩ | ro1 = = 105kΩ 491µA 873µA 493x10−6 ( ) RE = 1kΩ 36kΩ 4.7kΩ = 807Ω A= rπ 2 + (β o + 1)RE vo = 1kΩ 36kΩ rπ 1 gm1 ro1 (rπ 2 + (β o + 1)RE ) ii ro1 + rπ 2 + (β o + 1)RE A= (β o + 1)REQ vo = − 1kΩ 36kΩ 5.09kΩ gm1 ro1 (rπ 2 + (β o + 1)REQ ) ii rπ 2 + (β o + 1)REQ ) [ ( ] ) [ ( ] (1kΩ 36kΩ r )= (1kΩ 36kΩ 5.09kΩ)= 817Ω π1 [r (r o1 π2 | gm = 40(491µA) = 19.6mS ][ ] + (β o + 1)REQ ) = 105kΩ (2.86kΩ + (101)806Ω) = 46.8kΩ REQ = 1kΩ 36kΩ 4.7kΩ = 806Ω | (β o + 1)REQ rπ 2 + (β o + 1)REQ = (101)806Ω = 0.966 2.86kΩ + (101)806Ω ⎛ 1 ⎞ A = −(817Ω)(19.6mS )(46.8kΩ)(0.966) = −724 kΩ | Aβ = −724 kΩ⎜ − ⎟ = 20.1 ⎝ 36kΩ ⎠ A −724kΩ Atr = = = −36.0 kΩ 1+ Aβ 1+ 20.1 Note : Rin = Rin = (1kΩ 36kΩ 5.09kΩ) = 38.7Ω 1+ 20.1 ⎛ r +r ⎞ 1 | Rin = ⎜ REQ π 2 o1 ⎟ = 21.8Ω β o + 1 ⎠ 1+ Aβ ⎝ (1kΩ 36kΩ 5.09kΩ) = 817Ω = 82.2 Ω 1+ Aβ 9.94 ⎛ rπ 2 + ro1 ⎞ ⎛ 2.86kΩ + 105kΩ ⎞ ⎟ ⎜806Ω ⎟ ⎜1kΩ 36kΩ 4.7kΩ 101 ⎠ ⎝ 101 ⎠ ⎝ Rout = = = 46.2 Ω 1+ Aβ 9.94 v vo ii = 10−3 v i → Av = o = = −32.4 v i 1000ii Note that this amplifier can be analyzed as a shunt-series feedback amplifier. This is good for student practice - see Problem 17.32. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-13 17.24 *Problem 17.24 – Figure P17.23 VCC 5 0 DC 12 IDC 5 4 DC 500UA II 0 2 AC 1 *IX 0 7 AC 1 RS 2 0 1K C1 2 3 82UF Q1 4 3 0 NBJT Q2 5 4 6 NBJT RF 3 6 36K RE 6 0 1K C2 6 7 47UF RL 7 0 4.7K .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .OP .AC DEC 100 1E2 1E7 .PRINT AC VM(7) VP(7) VM(2) VP(2) .END Results: Atr = -34.4 kΩ, Rin = 36.8 Ω, Rout = 17.6 Ω -- Note that these values are highly sensitive to the precise value of rπ1. 17.25 0.002v + i gs v gs i 100 k Ω y11F = i1 v1 v ( - 1 MΩ = 10−6 S | y22F = 2 =0 ) 40 k Ω i2 v2 10 k Ω = 10−6 S | y12F = v1 =0 vgs = ii 100kΩ 1MΩ = (90.9kΩ)ii A= 10 k Ω ( i1 v2 ) ( 1MΩ = −10−6 S v1 =0 vo = −(2mS )(4.44kΩ)(90.9kΩ) = −8.08x105 ii A −8.08x105 −8.08x105 Atr = = = = −446 kΩ 1+ Aβ 1+ −8.08x105 −10−6 1.81 Rin ( )( ) (100kΩ 1MΩ) = 90.9kΩ = 50.2 kΩ = Rout = (1+ Aβ ) 1.81 (40kΩ 10kΩ 10kΩ 1MΩ) = 4.44kΩ = 2.45kΩ (1+ Aβ ) 1.81 17.26 17-14 ) | vo = − 2x10−3 v gs 40kΩ 10kΩ 10kΩ 1MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 i i gmv1 + RI Cπ rπ v1 Cµ R y12F = −sCµ | A = ZinA = RL vo rπo g mrπo RL =− gm ) =− ( ii sCµ RL + 1 s(Cπ + Cµ )rπo + 1 s(Cπ + Cµ )rπo + 1 [sCµ RL + 1] [ rπo ZinA | Zin = = 1+ Aβ s(Cπ + Cµ )rπo + 1 | Zin = [s(C π Zin = Zin ≅ ] rπo s(Cπ + Cµ )rπo + 1 1− [s(C π where rπo = rπ RI Cµ L g mrπo RL ] (−sC ) + Cµ )rπo + 1 [sCµ RL + 1] rπo (sCµ RL + 1) µ ] + Cµ )rπo + 1 [sCµ RL + 1]+ sCµ g mrπo RL rπo (sCµ RL + 1) rπo (sCµ RL + 1) = 2 ⎡ s (Cπ + Cµ )Cµ rπo RL + srπoCT + 1 R ⎤ s2 (Cπ + Cµ )Cµ rπo RL + srπo ⎢Cπ + Cµ (1+ g m RL )+ L ⎥ + 1 rπo ⎦ ⎣ rπo (sCµ RL + 1) ⎡ R ⎤ srπo ⎢Cπ + Cµ (1+ g m RL )+ L ⎥ + 1 rπo ⎦ ⎣ = rπo (sCµ RL + 1) srπoCT + 1 for ω << ωT ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-15 17.27 + M3 vo iref i o _ + M 3 i2 1 i r o1 g m2 2 ro1 i ref i1 v1 v y11F = = g o1 | y22F = 2 =0 i2 v2 1 v r g m2 A = o = ro1 = o1 1 iref 2 1+ g m3 g m2 g m3 Rin = ro1 = 1+ Aβ ro1 1+ µf 2 2 io = i2 = g m2vo = g m2 17-16 = = g m2 | y12F = v1 =0 A | Atr = = 1+ Aβ i1 v2 = g m2 v1 =0 ro1 2 1+ ro1 (g m2 ) 2 = ro1 2 + µf 1 36kΩ 2 = 973Ω | Note : Rin ≅ 72 gm 1+ 2 ro1 i µ f 1 + 2 ref | 1 g µf 1 io = = 0.973 iref µ f 1 + 2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 m2 v o _ 17.28 y11F = i1 v1 v = go1 F | y 22 = 2=0 io = α oi2 = α o gm 2v o | A= i2 v2 = gm 2 | y12F = v1 = 0 (β o + 1) i1 v2 β = β+2 v1 = 0 gm 2 ≅ gm 2 1 gm 2 vo (β o + 1) ≅ β o r = r = ro1 ≅ ro1 1 iref µ f + 2β o + 1 µ f o1 π 1 ro1 + rπ 3 + (β o + 1) gm 2 + Q 3 vo i ref _ io + β i β+2 2 r i2 g o1 ro1 1 1 ro1 m2 g m2 vo _ i ref (β o + 1) µ f + 2β o + 1 βo + 1 r 1 ≅ ro1 ≅ o1 = (β o + 1) g µ f β o + 2µ f + 2β o + 2 µ f gm1 1+ ro1 ( m2) µ f + 2β o + 1 Atr = A = 1+ Aβ Atr = 1 = 20.0 Ω 50mS | AI = io v g = α o gm 2 o = α o m 2 ≅ 1 iref iref gm1 ⎡ 1 ⎤ RinA = ro1 ⎢rπ 3 + (β o + 1) ⎥ ≅ ro1 2rπ 3 ≅ 2rπ 3 gm 2 ⎦ ⎣ RinA Rin = = 1+ Aβ Rin = ro1 2rπ 3 ro1 2rπ 3 r 2r 2r 2 ≅ ≅ o1 π 3 ≅ π 3 ≅ µ (β + 1) (β o + 1) g β o + 1 β o + 1 gm 3 1+ ro1 ( m 2 ) 1+ f o µ f + 2β o + 1 µ f + 2β o + 1 ro1 2rπ 3 40kΩ 4kΩ = = 36.0 Ω βo + 1 101 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-17 17.29 *Problem 17.29 - BJT Wilson Source *Current gain = 100 VCC 0 3 DC -6 IREF 0 1 DC 100UA Q1 1 2 0 NBJT Q2 2 2 0 NBJT Q3 3 1 2 NBJT .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .OP .TF I(VCC) IREF β o ro3 100(55.3V ) = = 27.7 MΩ | SPICE : 29.9 MΩ .END 2 2(100µA) *Problem 17.29 - BJT Wilson Source *Current gain = 10K VCC 0 3 DC -6 IREF 0 1 DC 100UA Q1 1 2 0 NBJT Q2 2 2 0 NBJT Q3 3 1 2 NBJT .MODEL NBJT NPN BF=10K VA=50 IS=1E-15 .OP .TF I(VCC) IREF .END SPICE : 799 MΩ *Problem 17.29 - BJT Wilson Source *Current gain = 1MEG VCC 0 3 DC -6 IREF 0 1 DC 100UA Q1 1 2 0 NBJT Q2 2 2 0 NBJT Q3 3 1 2 NBJT .MODEL NBJT NPN BF=1MEG VA=50 IS=1E-15 .OP .TF I(VCC) IREF 55.3V µ f 1ro3 = 40(51.4) = 1.14 GΩ | SPICE : 1.08 GΩ .END 100µA 17-18 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.30 + is v 100 k Ω 11 k Ω 20 k Ω - io 1k Ω 1 + _ 5kΩ 4000 v 1 909 Ω 10 k Ω 1kΩ g11F = i1 1 v = | g22F = 2 v1 i = 0 11kΩ i2 2 ( = 1kΩ 10kΩ = 909Ω | g12F = v1 = 0 =− v1 = 0 1kΩ 1 =− 10kΩ + 1kΩ 11 ) A= i2 4000 = − 100kΩ 11kΩ 20kΩ = −384.84x103 ii (5 + 1+ 0.909)kΩ Ai = A = 1+ Aβ Rin = i1 i2 −3.84x103 = −10.97 ⎛ 1⎞ 3 1+ −3.84x10 ⎜ − ⎟ ⎝ 11⎠ ( ) (100kΩ 11kΩ 20kΩ) = 6.63kΩ = 18.9 Ω (1+ Aβ ) 351 Rout = (5kΩ + 1kΩ + 0.909kΩ)(1+ Aβ )= (6.91kΩ)(351)= 2.43MΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-19 17.31 + A RI iI + RL vo 10 k Ω 150 k Ω R1 - 20 k Ω R2 2kΩ Feedback Network i1 1 v = | g22F = 2 v1 i = 0 22kΩ i2 g11F = 2 g11T = v1 = 0 i1 i2 =− v1 = 0 1 1 1 v T + = | g22 = 1.82kΩ + 1kΩ = 2.82kΩ | g21A = 2 20kΩ 22kΩ 10.5kΩ v1 A=− g T 11 A = 1+ Aβ Rin = A 21 (G + g )(g I Ai = = 2kΩ 20kΩ = 1.82kΩ | g12F = T 22 + RL ) =− (150kΩ 10.5kΩ) = 9.81kΩ = 35.2 Ω 1+ 278 Rout = (10kΩ + 2.82kΩ)(1+ Aβ )= (12.8kΩ)(279) = 3.57 MΩ 17-20 = 4000 i2 = 0 4000 1 = −3060 | β = g12F = − ⎛ 1 11 1 ⎞ + ⎟(2.82kΩ + 10kΩ) ⎜ ⎝150kΩ 10.5kΩ ⎠ −3060 = −11.0 | Aβ = 278 ⎛ 1⎞ 1+ (−3060)⎜ − ⎟ ⎝ 11⎠ (1+ Aβ ) 2kΩ 1 =− 20kΩ + 2kΩ 11 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.32 io +12 V Q 1 500 µA Q Q RI 2 ii 1 4.7 k Ω Q2 1k Ω 36 k Ω 36 k Ω 1k Ω 1k Ω IC1 = 500µA − IB 2 | IE 2 = IB1 + IC1 = 500µA − IE 2 = 37 37IB1 + 700µA 101 36000IB1 + 0.7 I = 37IB1 + 700µA | IB 2 = E 2 101 1000 = 493µA − 0.366IB1 → IC1 = 491.2µA IC1 100 + 700µA = 881.7µA | IC 2 = IE 2 = 873µA 100 101 Q Q io 2 4.7k Ω 1 36 k Ω 0.001v i g11F = 1kΩ i1 1 v F = | g22 = 2 v1 i = 0 37 kΩ i2 2 1kΩ 37kΩ = 974 Ω | rπ 1 = 1kΩ 1k Ω 36 k Ω = 36kΩ 1kΩ = 973 Ω | g12F = v1 = 0 i1 i2 =− v1 = 0 1kΩ 1 =− 1kΩ + 36kΩ 37 100(0.025) 100(0.025) = 5.09 kΩ | rπ 2 = = 2.86 kΩ 491µA 873µA A= ⎛ ⎞ 4700Ω io 974Ω =− ⎟ = −1340 (−100)(101)⎜ ⎝ 973Ω + 4700Ω ⎠ 974Ω + 5090Ω ii Ai = A = 1+ Aβ −1340 −1340 = = −36.0 ⎛ 1⎞ 37.2 1+ (−1340)⎜ − ⎟ ⎝ 37 ⎠ | 1 + Aβ = 37.2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-21 v o 973io i = = 0.973 o = −35.0 v i 1000ii ii Av = (1kΩ 37kΩ r ) = (1kΩ 37kΩ 5.09kΩ) = 22.0 Ω 50 + 1.6 = 105kΩ 1+ Aβ 37.2 493x10−6 ⎛ rπ 2 + ro1 ⎞ ⎛ 5.09kΩ + 105kΩ ⎞ ⎜1kΩ 36kΩ 4.7kΩ ⎟ ⎜1kΩ 36kΩ 4.7kΩ ⎟ 101 101 ⎠ ⎝ ⎝ ⎠ = = = 12.5 Ω 1+ Aβ 37.2 π1 Rin = Rout | ro1 = 17.33 + 2kΩ + - vi 20 k Ω v i 1k Ω 1 - + _ 4000 v o 5kΩ 1 5k Ω 5kΩ 5kΩ v1 v = 5 kΩ | z22F = 2 i1 i =0 i2 z11F = 2 A= = 5 kΩ | β = z12F = i1 =0 v1 = 5 kΩ i2 i =0 1 ⎛ ⎞ io 4000 20kΩ = ⎜ ⎟ = 0.269 vs 2kΩ + 20kΩ + 5kΩ ⎝ 5kΩ + 1kΩ + 5kΩ ⎠ Atr = io A 0.269 v i = = = 0.200 mS | o = −5000 o = −1.00 | 1+ Aβ = 1350 vs 1+ Aβ 1+ 0.269(5000) vs vs Rin = (2kΩ + 20kΩ + 5kΩ)(1+ Aβ ) = (27kΩ)(1350)= 36.5 MΩ Rout = (5kΩ + 1kΩ + 5kΩ)(1+ Aβ )= (11kΩ)(1350) = 14.9 MΩ 17-22 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.34 RI vi 2 kΩ A + + RL + vo 5 kΩ - R1 5 kΩ Feedback Network v1 v = 5 kΩ | z22F = 2 i1 i =0 i2 z11F = 2 = 5 kΩ | β = z12F = i1 =0 v1 = 5 kΩ i2 i =0 1 T z11T = 5kΩ + 20kΩ = 25 kΩ | z22 = 5kΩ + 1kΩ = 6 kΩ | z21A = A= z21A (R + z )(z I Atc = T 11 T 22 + RL ) = v2 i1 = 20kΩ(4000) = 80 MΩ i2 =0 80 MΩ = 0.269 S (2kΩ + 25kΩ)(6kΩ + 5kΩ) A 0.269 = = 2.00x10−4 S | Aβ = 1345 1+ Aβ 1+ 0.269(5kΩ) ( ) Note : Rin = RI + z11T (1+ Aβ ) = (27kΩ)(1346) = 36.3 MΩ ( ) T + RL (1+ Aβ )= (11kΩ)(1346) = 14.8 MΩ Rout = z22 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-23 17.35 RI + - vi io i1 β i rπ o1 io RE RI + - vi RE + vo - i2 i1 rπ β o i1 RE + - i2 RE By carefully drawing the circuit, it can be represented as a series-series feedback amplifier. In particular, rπ and the current generator are connected within the feedback network. i βo A= 2 = | β = z12F = RE v s RS + rπ + RE βo io A βo RS + rπ + RE = = = βo v s 1+ Aβ 1+ RE RS + rπ + (β o + 1)RE RS + rπ + RE Atc = Av = v o io RE βo (β o + 1)RE = (β o + 1)RE = = v s v s α o RS + rπ + (β o + 1)RE βo RS + rπ + (β o + 1)RE ⎛ ⎞ βo Rin = RinA (1+ Aβ ) = (RS + rπ + RE )⎜1+ RE ⎟ = RS + rπ + (β o + 1)RE ⎝ RS + rπ + RE ⎠ Both answers agree with our previous direct derivations. 17-24 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.36 Av = Av = Atc = + - β o RL β o RL = RS + rπ + (β o + 1)RE RS + rπ + RE + β o RE βo RS + rπ + RE 1+ βo RS + rπ + RE βo RS + rπ + RE R I vi RL = RE Atc RL 1+ Atcβ | β = RE i i1 o β i rπ o1 io RE + vo - + - R i1 R rπ I vi E i2 β i o 1 R E + - i R 2 E By carefully drawing the circuit, it can be represented as a series-series feedback amplifier. In particular, rπ and the current generator are connected within the feedback network. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-25 17.37 i o Q io 3 Q3 i ref iref r o1 + v r o1 g g11F = v 1 - g F | g22 = 2 Ai = m2 m2 m1 1 i1 1 = v1 i = 0 ro1 io = iref ro1 1 g 1 v2 i2 βo ro1 + rπ 3 + (β o3 + 1) = v1 = 0 1 gm 2 1 gm 2 ≈ iref | g12F = β o ro1 ro1 + 2rπ 3 + i1 i2 1 gm 2 = v1 = 0 gm1 ≅1 gm 2 | A= β oµ f io = ≈ βo iref µ f + 2β o + 1 A βo = = α o ≈ 1 which is correct. 1+ Aβ 1+ β o (1) ⎛ 1 ⎞ ro1 ⎜ rπ 3 + (β o3 + 1) ⎟ gm 2 ⎠ 2rπ ⎝ 2 ≈ = which is correct. Rin = 1+ β o β o gm ⎞ ⎛ 1 β o3 ⎜ ⎛ ⎞ βo gm 2 ⎟ ⎟ = (1+ β o )ro ⎜⎜1+ ⎜ Rout = (1+ β o )ro 3 1+ ⎟ ≈ β o ro − not correct! µ f + β o + 1⎟⎠ ⎜ r +r + 1 ⎟ ⎝ ⎟ ⎜ o1 π3 gm 2 ⎠ ⎝ 17-26 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.38 5 Q3 Q R I + - 1 Q RL3 2 1 RL2 RL1 v i 3 2 4 RF R E1 R E2 The amplifier is not a two-port. It has five separate terminals. It can be analyzed correctly as a series-shunt configuration with the output defined at terminal 4. In the series-shunt configuration, RL is absorbed into the amplifier thereby making it a two-port. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-27 17.39 R = r o2 M4 M4 Amplifier ii RI M3 M3 R = r o2 Feedback Network (a) (b) (c) Yes, see figure. g r 1 ro 3 ≅ A(i) = ro 3 m 4 o2 1+ gm 4 ro2 ro 2 ro 2 | β = gm 3 ro2 | Aβ = gm 3 ro 3 = µ f 3 A A Rout = µ f 4 ro 2 | Rout = Rout (1+ Aβ ) = µ f 4 (1+ µ f 3 )ro2 Also, RinA = ro 3 | Rin = RinA r 1 = o3 ≅ (1+ Aβ ) 1+ µ f 3 gm 3 (d) ix + vgs4 - g m4 v r + - vx o4 gs4 + r v o3 g m3 v gs3 gs3 ro2 - v x = (ix − gm 4 v gs4 )ro4 + ix ro2 | v gs4 = (−µ f 3v gs3 − v gs3 )= −ix ro 2 (µ f 3 + 1) v x = ix ro 4 + ix ro 2 + gm 4 ro 4 (1+ µ f 3 )ix ro2 | Rout = µ f 4 (1+ µ f 3 )ro 2 17-28 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 (e) ⎡ 50 + 8⎤ ⎢ µf = gm ro ≅ 2(0.75 x10 )(10 ) −4 ⎥ = (0.387mS )(580kΩ) = 194 ⎢⎣ (10 )⎥⎦ −3 −4 Rout = µ f 4 (1 + µ f 3 )ro2 = 194 (195)(580kΩ) = 21.9 GΩ (f) SPICE yields 28.0 GΩ values from SPICE.  with the formula above using the parameter 17.40 + A R1 R2 R 2 + vx R1 vo _ Note: The loading effects of the feedback network must be carefully included. R1 R2 = 1kΩ 9.1kΩ = 901Ω | For vS = 0, IC = α F I = 198µA | rπ = T= T= 100(0.025V ) (β o + 1)(R1 + R2 ) ⎛ R1 ⎞ vo RID = A) ⎟ ⎜ ( vx RID + 901Ω RO + rπ + (β o + 1)(R1 + R2 )⎝ R1 + R2 ⎠ 198µA = 12.6kΩ ⎛ ⎞ (101)(10.1kΩ) vo 40kΩ 1kΩ = 316) ⎜ ⎟ = 30.2 ( vx 40kΩ + 901Ω 1kΩ + 12.6kΩ + (101)(10.1kΩ)⎝1kΩ + 9.1kΩ ⎠ 17.41 v (β o + 1)R T = o = gm 2 (ro2 ro4 ) | gm1 = 40(10−4 )= 4.00mS vx (ro2 ro4 )+ rπ 3 + (β o + 1)R ro2 = 100(0.025) 50 + 1.4 50 + 11.3 = 514kΩ | ro4 = = 613kΩ | rπ 3 = = 2.08kΩ −4 −4 10 10 (12V /10kΩ) T = (4 x10−3 )(280kΩ) (101)10kΩ 280kΩ + 2.08kΩ + 101(10kΩ) = 876 (58.9 dB) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-29 17.42 Q3 ix i + i v1 r o1 T= g - 1 m2 (β o + 1)µ f io ro (101)(2000) = 91.8 = (β o + 1) = = 1 ix µ f + 2β o + 1 2000 + 200 + 1 ro + rπ + (β o + 1) gm 17.43 Q Q v x Q 2 Q 1 36 k Ω + - R 1k Ω 1k Ω 1k Ω||36k Ω||4.7k Ω EQ vx 36 k Ω 1k Ω 36 k Ω y11F = rπ 1 = T= i1 v1 v = 2=0 1 36kΩ F | y 22 = i2 v2 = v1 = 0 1 36kΩ 1kΩ i1 v2 =− v1 = 0 1 36kΩ 100(0.025) 100(0.025) 50 + 1.6 = 5.09kΩ | rπ 2 = = 2.86kΩ | ro1 = = 105kΩ 491µA 873µA 493x10−6 rπ 2 + (β o + 1)REQ vo 1 = 1kΩ 36kΩ rπ 1 gm1 ro1 (rπ 2 + (β o + 1)REQ ) v s 36kΩ ro1 + rπ 2 + (β o + 1)REQ ) [ ( (1kΩ 36kΩ r ) = (1kΩ 36kΩ 5.09kΩ) = 0.0227 π1 36 kΩ [r (r o1 | y12F = π2 36kΩ ][ ] | gm = 40(491µA) = 19.6mS ] + (β o + 1)REQ ) = 105 kΩ (2.86 kΩ + (101)806Ω) = 46.8kΩ rπ 2 + (β o + 1)REQ 2.86kΩ + (101)806Ω = = 0.430 ro1 + rπ 2 + (β o + 1)REQ 105 kΩ + 2.86 kΩ + (101)806Ω T = (0.0227)(19.6mS )(46.8kΩ)(0.430) = 8.95 17-30 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 2 1 REQ + 806 Ω - vo 17.44 C v1 v2 1 vx vx + R R 1 2 C ⎡sC1Vx ⎤ ⎡sC1 + G1 + G2 ⎢ ⎥=⎢ −G2 ⎣ 0 ⎦ ⎣ 2 −G2 ⎤⎡V1 ⎤ ⎥⎢ ⎥ sC2 + G2 ⎦⎣V2 ⎦ V2 = sC1G2 Vx ∆ ∆ = s 2C1C2 + s[C1G2 + C2 (G1 + G2 )]+ G1G2 T= V2 = Vx s R2C2 ⎡ 1 ⎤ 1 1 ⎥+ s 2 + s⎢ + ⎢⎣ R2C2 (R1 R2 )C1 ⎥⎦ R1R2C1C2 17.45 R v1 vx 1 v2 vo + C1 K C2 R 2 ⎡G1Vx ⎤ ⎡s(C1 + C2 ) + G1 ⎢ ⎥=⎢ −sC2 ⎣ 0 ⎦ ⎣ −sC 2 ⎤⎡V1 ⎤ ⎥⎢ ⎥ sC2 + G2⎦⎣V2 ⎦ Vo = KV2 ∆ = s 2C1C2 + s[C1G2 + C2 (G1 + G2 )]+ G1G2 T= Vo =K Vx s 1 R1C1 ⎡ 1 ⎤ 1 1 ⎥+ s2 + s⎢ + ⎢⎣ R2C2 (R1 R2 )C1 ⎥⎦ R1R2C1C2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-31 17.46 *Problem 17.46 - Fig. P17.17 VCC 4 0 DC 10 IS 5 0 DC 200U VS 1 0 DC 0 Q1 4 3 5 NBJT RID 1 8 40K RO 2 3 1K E1 2 0 1 8 316.2 R2 6 5 7.5K R1 8 0 1K VB 7 8 DC 0 VX 7 6 AC 0 IX 0 7 AC 1 *VX 7 6 AC 1 *IX 0 7 AC 0 .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .OP .AC LIN 1 10 10 .PRINT AC IM(VX) IP(VX) IM(VB) IP(VB) VM(7) VP(7) VM(6) VP(6) .END Results: I(VX) = 0.9759 A, I(VB) = 0.0241 A, V(7) = 3.078 mV, V(6) = -0.9969 V −.9969V 0.9759A = 324 | Ti = = 40.5x10 4 3.078mV 0.0241A 324 (40.5) −1 T T −1 R2 1+ Tv 1+ 324 T= v i = = 35.8 | = = = 7.83 2 + Tv + Ti 2 + 324 + 40.5 R1 1+ Ti 1+ 40.5 Tv = − 17-32 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.47 *Problem 17.47 - Fig. P17.18 BJT Op-amp VCC 8 0 DC 12 VEE 9 0 DC -12 IS 2 9 DC 200U VS 1 0 DC 0 Q1 4 1 2 NBJT Q2 5 3 2 NBJT Q3 4 4 8 PBJT Q4 5 4 8 PBJT Q5 8 5 6 NBJT R 6 9 10K VB 7 3 DC 0 VX 7 6 AC 0 IX 0 7 AC 1 *VX 7 6 AC 1 *IX 0 7 AC 0 .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .MODEL PBJT PNP BF=100 VA=50 IS=1E-15 .OP .AC LIN 1 10 10 .PRINT AC IM(VX) IP(VX) IM(VB) IP(VB) VM(7) VP(7) VM(6) VP(6) Results: I(VX) = 1.000 A, I(VB) = 3.703 x 10-5 A, V(7) = 1.188 mV, V(6) = -1.000 V Tv = − −.9988V 1.000A = 841 | Ti = = 2.70x10 4 1.188mV 37.03µA 841(2.70x10 4 )−1 Tv Ti −1 R2 1+ Tv 1+ 841 T= = = 816 | = = = 0.0312 4 R1 1+ Ti 2.70x10 4 2 + Tv + Ti 2 + 841+ 2.70x10 17.48 The circuit description is the same as Problem 17.46 except for the change in the values of R1 and R2. R2 6 5 300K R1 8 0 40K Results: I(VX) = 0.9548 A, I(VB) = 45.19 mA, V(7) = 3.011 mV, V(6) = -0.9970 V −.9970V 0.9548A = 331 | Ti = = 21.1 3.011mV 45.19mA 331(21.1) −1 R2 1+ Tv 1+ 331 T T −1 = = 19.7 | = = = 15.0 T= v i R1 1+ Ti 1+ 21.1 2 + Tv + Ti 2 + 331+ 21.1 Tv = − ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-33 17.49 *Problem 17.49 - Fig. 17.2(b) IS 0 1 DC 0 RS 1 0 1K RID 1 0 15K RO 2 3 1K E1 3 4 1 0 5000 RL 2 0 4.7K R2 4 0 1K R1 4 6 36K VB 7 1 DC 0 VX 7 6 AC 0 IX 0 7 AC 1 *VX 7 6 AC 1 *IX 0 7 AC 0 .OP .AC LIN 1 10 10 .PRINT AC IM(VX) IP(VX) IM(VB) IP(VB) VM(7) VP(7) VM(6) VP(6) .END Results: I(VX) = 0.9500 A, I(VB) = 49.97 mA, V(7) = 1.271 mV, V(6) = -0.9987 V −.9987V 0.9500A = 786 | Ti = = 19.0 1.271mV 49.97mA 786(19.0) −1 R2 1+ Tv 1+ 786 T T −1 = = 18.5 | = = = 39.4 T= v i R1 1+ Ti 1+ 19.0 2 + Tv + Ti 2 + 786 + 19.0 Tv = − 17-34 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.50 *Problem 17.50 VCC 5 0 DC 6 IREF 0 1 DC 100UA Q1 1 4 0 NBJT Q2 4 4 0 NBJT Q3 5 3 4 NBJT IX 0 2 DC 0 VX1 2 1 DC 0 VX2 2 3 DC 0 .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .OP .TF I(VX1) IX ---> 0.9910 *.TF I(VX2) IX ---> 9.043 x 10-3 .END *Problem 17.50 VCC 5 0 DC 6 IREF 0 1 DC 100UA Q1 1 4 0 NBJT Q2 4 4 0 NBJT Q3 5 3 4 NBJT IX 0 2 DC 0 VX1 2 1 DC 0 VX2 2 3 DC 0 .MODEL NBJT NPN BF=100 VA=50 IS=1E-15 .OP .TF V(1) VX1 ---> -0.9990 *.TF V(2) VX1 ---> 1.012 x 10-3 .END −0.9990 0.9910 Tv = − = 987 | Ti = = 110 −3 1.012x10 9.043x10−3 987(110) −1 R2 1+ 987 = 98.8 | = = 8.90 T= 2 + 987 + 110 R1 1+ 110 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-35 17.51 Since the output resistance of the amplifier is zero (R2 = 0), the simplified method can be used: T = Tv. *Problem 17.51 VS 1 0 DC 0 C1 1 2 0.005UF C2 2 3 0.005UF R1 2 7 2K R2 3 0 2K E1 4 0 3 0 1 R 4 5 31.83 C 5 0 1NF E2 6 0 5 0 2 VX 7 6 AC 1 .OP .AC DEC 100 1 1E6 .PROBE V(6) V(7) .END 0 dB T = V(6)/V(7) -20 dB Frequency -40 dB 1.0 Hz 17-36 100 Hz 10 KHz 1.0 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.52 (a ) With gain A = 0, RinD = RI + Rid + R1 R2 + Ro RL RinD [ ] = 1kΩ + 20kΩ + 5kΩ [45kΩ + 1kΩ 5kΩ]= 25.5kΩ With the input open - circuited, the current in Rid is zero, and so TOC = 0. With the input set to zero, The Thevenin equivalent looking back into R1 is ⎤ ⎡ ⎛ 5kΩ ⎞⎤⎡ 5kΩ ⎢ ⎥ = 328 and Vth = ⎢4000⎜ ⎟⎥ ⎝ 5kΩ + 1kΩ ⎠⎦⎢⎣ 5kΩ + 45kΩ + 5kΩ 1kΩ ⎥⎦ ⎣ [ ] ( [ ) ] Rth = R1 R2 + Ro RL = 5kΩ 45kΩ + 5kΩ 1kΩ = 4.51kΩ TSC = 328 ⎛ 1+ 257 ⎞ 20kΩ = 257 | Rin = 25.5kΩ⎜ ⎟ = 6.58 MΩ 4.51kΩ + 20kΩ + 1kΩ ⎝ 1+ 0 ⎠ With gain v s and A = 0, [ ( )] [ )] ( RoutD = RL Ro R2 + R1 (Rid + RI ) = 5kΩ 1kΩ 45kΩ + 5kΩ (20kΩ + 1kΩ) = 819Ω With the output shorted, TSC = 0. With the output open - circuited, TOC = 257 ⎛ 1+ 0 ⎞ Rout = 819Ω⎜ ⎟ = 3.17 Ω | Rin and Rout agree with both Prob. 17.15 and SPICE. ⎝1+ 257 ⎠ (b) With gain A = 0, [ ] [ ] RinD = RI Rid R1 + R2 (Ro + RL ) = 100kΩ 20kΩ 10kΩ + 1kΩ (1kΩ + 5kΩ) = 6.57kΩ With the input short - circuited, TSC = 0. With the input open - circuited, TOC = TOC = − 4000 [ ( RL + Ro + R2 R1 + RI Rid )] R2 ( R2 + R1 + RI Rid ⎡ 1kΩ ⎢ 5kΩ + 1kΩ + 1kΩ 10kΩ + 100kΩ 20kΩ ⎢⎣1kΩ + 10kΩ + 100kΩ 20kΩ 4000 [ ⎛ 1+ 0 ⎞ Rin = 6.57kΩ⎜ ⎟ = 18.9 Ω ⎝1+ 346 ⎠ )] ( | ( (R ) I Rid ) ⎤ ⎥ 100kΩ 20kΩ = −346 ⎥ ⎦ ) ( ) Since the circuit is series feedback at the output, we look into the circuit between ground and the bottom of R L . With gain A = 0, [ ( )] [ ( )] RoutD = RL + Ro + R2 R1 + RI Rid = 5kΩ + 1kΩ + 1kΩ 10kΩ + 100kΩ 20kΩ = 6.96kΩ With the output open, io = 0, and TOC = 0. With the output short - circuited, TSC is TSC = − 4000 [ ( RL + Ro + R2 R1 + RI Rid R2 )]R + R + (R 2 1 I Rid (R ) I ) Rid = −346 ⎛ 1+ 346 ⎞ Rout = 6.96kΩ⎜ ⎟ = 2.42 MΩ | Rin and Rout agree with both Prob. 17.30 and SPICE. ⎝ 1+ 0 ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-37 (b) cont. We can instead choose to look at the shunt output. With gain A = 0, { [ ( RoutD = RL Ro + R2 R1 + RI Rid )]}= 5kΩ {1kΩ + 1kΩ [10kΩ + (100kΩ 20kΩ)]}= 1.40kΩ 4000 With the output shorted, TSC = − [ ( Ro + R2 R1 + RI Rid )] R2 ( R2 + R1 + RI Rid (R ) I ) Rid = −1227 With the output open - circuited, TOC = − 4000 [ ( RL + Ro + R2 R1 + RI Rid )] R2 ( R2 + R1 + RI Rid (R ) I ) Rid = −346 ⎛ 1+ 1227 ⎞ Rout = 1.40kΩ⎜ ⎟ = 4.954 kΩ and removing the 5kΩ resistor yields Rout = 544kΩ. ⎝ 1+ 346 ⎠ The error is due to loss of significance in the calculations. If we remove RL from across the output, RoutD = 1.94kΩ, TSC = −1227, and TOC = 0. ⎛ 1+ 1227 ⎞ Rout = 1.94kΩ⎜ ⎟ = 2.38 MΩ | Rout again agrees with both Prob. 17.30 and SPICE. ⎝ 1+ 0 ⎠ (c) With gain A = 0, R = R + R + R (R inD I 1 id o + RL )= 2kΩ + 20kΩ + 5kΩ (1kΩ + 5kΩ)= 24.7kΩ When the input is open - circuited, zero current exists in Rid and TOC = 0. With the input short - circuited, ⎞ ⎛ 4000 R1 TSC = ⎟ Rid ⎜ RL + Ro + R1 (Rid + RI ) ⎝ R1 + Rid + RI ⎠ [ TSC = ] ⎞ ⎛ 5kΩ ⎟20kΩ = 1471 ⎜ 5kΩ + 1kΩ + 5kΩ (20kΩ + 2kΩ) ⎝ 5kΩ + 20kΩ + 2kΩ ⎠ 4000 [ ] ⎛1+ 1471⎞ Rin = 24.7kΩ⎜ ⎟ = 36.3 MΩ ⎝ 1+ 0 ⎠ With gain A = 0, (remember, this is series feedback and we look into the bottom of R L ) [ ] [ ] RoutD = RL + Ro + R1 (Rid + RI ) = 5kΩ + 1kΩ + 5kΩ (20kΩ + 2kΩ) = 10.1kΩ With the output open - circuited, TOC = 0. With the output shorted, ⎛1+ 1471⎞ TSC = 1730, the same as above, and Rout = 10.1kΩ⎜ ⎟ = 14.9 MΩ ⎝ 1+ 0 ⎠ Rin and Rout agree with both Prob. 17.33 and SPICE. 17-38 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 (d) With gain A = 0, [ ( )] [ ( )] RinD = RI Rid RF + RL Ro = 100kΩ 20kΩ 36kΩ + 5kΩ 1kΩ = 11.5kΩ With the input short - circuited, TSC = 0. When the input is open - circuited and using a Norton equivalent, ( ) ) ( RL Ro ⎛ 4000 ⎞ TOC = ⎜ ⎟ ⎝ Ro ⎠ RL Ro + RF + RI Rid (R R ) ) ⎛ 4000 ⎞ (5kΩ 1kΩ) =⎜ ⎟ (100kΩ 20kΩ)= 1040 ⎝ 1kΩ ⎠ (5kΩ 1kΩ)+ 36kΩ + (100kΩ 20kΩ) ( TOC ⎛ 1+ 0 ⎞ Rin = 11.5kΩ⎜ ⎟ = 11.0 Ω ⎝1+ 1040 ⎠ With gain A = 0, [ ( )] I id [ ( )] RoutD = RL Ro RF + RI Rid = 5kΩ 1kΩ 36kΩ + 100kΩ 20kΩ = 820Ω With the output short - circuited, TSC = 0. With the output open, ⎛ 1+ 0 ⎞ TOC = 1040, the same as above, and Rout = 820Ω⎜ ⎟ = 0.788 Ω ⎝ 1+ 1040 ⎠ Rin and Rout agree with both Prob. 17.21 and SPICE. 17.53 IC1 = 500µA − IB 2 | IE 2 = IB1 + IC1 = 500µA − 37IB1 + 700µA 101 36000IB1 + 0.7 I = 37IB1 + 700µA | IB 2 = E 2 1000 101 = 493µA − 0.366IB1 → IC1 = 491.2µA IC1 100 + 700µA = 881.7µA | IC 2 = IE 2 = 873µA | gm1 = 40(491.2µA) = 19.6mS 101 100 100(0.025) 100(0.025) 50 + 1.6 = 5.09kΩ | rπ 2 = = 2.86kΩ | ro1 = = 105kΩ rπ 1 = 493x10−6 491µA 873µA IE 2 = 37 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-39 After replacing vi and R I with their Norton equivalent, and with g m1 = 0, ⎡ ⎛ r + r ⎞⎤ RinD = RI rπ 1 ⎢RF + RE RL ⎜ π 2 o1 ⎟⎥ ⎝ β o 2 + 1 ⎠⎦ ⎣ ⎡ ⎛ 2.86kΩ + 105kΩ ⎞⎤ RinD = 1kΩ 5.09kΩ ⎢36kΩ + 1kΩ 4.7kΩ ⎜ ⎟⎥ = 817Ω ⎝ ⎠⎦ 101 ⎣ With the input shorted, TSC = 0. With the input open and starting at the output of Q1, ⎫⎪⎡ R r ⎧⎪ (β o 2 + 1) RE RL (RF + RI rπ 1 ) ( I π1) ⎤⎥ TOC = (−gm1ro1 )⎨ ⎬⎢ ⎪⎩ ro1 + rπ 2 + (β o2 + 1) RE RL (RF + RI rπ 1 ) ⎪⎭⎢⎣ RF + (RI rπ 1 )⎥⎦ ⎫⎪⎡ ⎧⎪ ⎤ (101) 1kΩ 4.7kΩ (36kΩ + 1kΩ 5.09kΩ) 1kΩ 5.09kΩ ⎥ TOC = (−2062)⎨ ⎬⎢ ⎪⎩105kΩ + 2.86kΩ + (101) 1kΩ 4.7kΩ (36kΩ + 1kΩ 5.09kΩ) ⎪⎭⎢⎣ 36kΩ + (1kΩ 5.09kΩ)⎥⎦ [ ] [ [ [ ] ] ] TOC = (−2062)(0.403)(0.0227) = −18.9 ⎛ 1+ 0 ⎞ Rin = 817Ω⎜ ⎟ = 41.2Ω ⎝ 1+ 18.9 ⎠ r +r 2.86kΩ + 105kΩ RoutD = RE RL (RF + RI rπ 1 ) π 2 o1 = 1kΩ 4.7kΩ (36kΩ + 1kΩ 5.09kΩ) = 460Ω (β o 2 + 1) (101) ⎛ 1+ 0 ⎞ TSC = 0, TOC = 18.9, Rout = 460Ω⎜ ⎟ = 23.1Ω | The results agree with SPICE. ⎝1+ 18.9 ⎠ 17-40 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.54 ⎡ 100(0.025V ) r + Ro ⎤ With gain A = 0, RinD = Rid + R1 ⎢R2 + π = 12.5kΩ ⎥ | rπ = βo + 1 ⎦ 200µA ⎣ ⎡ 12.5kΩ + 1kΩ⎤ RinD = 40kΩ + 1kΩ ⎢7.5kΩ + ⎥⎦ = 40.9kΩ ⎣ 101 With the input open - circuited, the current in Rid is zero, and so TOC = 0. With the input set to zero, the load on the emitter follower is RLEQ = R2 + (R1 Rid ) = 7.5kΩ + (1kΩ 40kΩ) = 8.48kΩ TSC = A (β o + 1)RLEQ Ro + rπ + (β o + 1)RLEQ ⎛ 0.976kΩ ⎞ 101(8.48kΩ) (R1 Rid ) = 316 ⎜ ⎟ = 35.8 R2 + (R1 Rid ) 1kΩ + 12.5kΩ + 101(8.48kΩ) ⎝ 8.48kΩ ⎠ ⎛1+ 35.8 ⎞ Rin = 40.9kΩ⎜ ⎟ = 1.51 MΩ ⎝ 1+ 0 ⎠ ⎛r + R ⎞ o With gain A = 0, RoutD = R2 + (R1 Rid ) ⎜ π ⎟ = 8.48kΩ 134Ω = 132Ω ⎝ βo + 1 ⎠ With the output shorted, TSC = 0. With the output open - circuited, TOC = 32.0. ⎛ 1+ 0 ⎞ Rout = 132Ω⎜ ⎟ = 3.59 Ω | Rin and Rout agree with both Prob. 18.18 and SPICE. ⎝1+ 35.8 ⎠ [ ] 17.55 1/g m3 Q3 Q4 Q4 i i Q5 i Q1 v ref Q2 r o1 R Q5 Q2 i R || 1.33r π2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-41 RinD = 4rπ 1 = 100kΩ (See analysis below **.) ⎡ (β o 5 + 1)(R 1.33rπ 2 ) ⎤ ⎥ With the input shorted, TSC = gm 2 ro 2 ro 4 (β o 5 + 1)(R 1.33rπ 2 ) Ω⎢ ⎢⎣ rπ 5 + (β o 5 + 1)(R 1.33rπ 2 )⎥⎦ [ Avef = ] (β o 5 + 1)(R 1.33rπ 2 ) (101)(10kΩ 33.3kΩ) = = 0.997 rπ 5 + (β o 5 + 1)(R 1.33rπ 2 ) 2.08kΩ + (101)(10kΩ 33.3kΩ) [ ] TSC = 40(100µA) 500kΩ 500kΩ (101)(10kΩ 33.3kΩ) (0.997) = 757 With the input open, TOC ≅ − 2i 2 2 ro2 ro 4 )Avef ≅ − ro2 ro 4 )Avef ≅ − (ro 2 ro 4 )(0.997) ≅ −0.997 ( ( 1 vi ro1 ro1 + gm 3 ⎛ 1+ 757 ⎞ Rin = 100kΩ⎜ ⎟ = 38.0MΩ ⎝1+ 0.997 ⎠ RoutD = R 1.33rπ 1 rπ 5 + (ro2 ro 4 ) β o5 + 1 = 10kΩ 33.3kΩ 2.08k + (500kΩ 500kΩ) 101 = 757. With the output shorted, TSC = 0 = 1.88kΩ With the output open, TOC ⎛ 1+ 0 ⎞ Rin = 1.88kΩ⎜ ⎟ = 2.48 Ω. ⎝1+ 757 ⎠ The values of R in and R out agree well with simulation when the effect of imbalance due to offset voltage is considered. (Try a buffered current mirror in SPICE.) -v i/4 vi + - + rπ v +µf vi /2 + ro v 1 - 2 ro g m v1 gm v 2 rπ - ve ** The input resistance to the differential pair with active load is 4rπ rather than the 2rπ that one might expect. Because of the high gain (µf /2) to the output node, a significant current is fed back through ro2 . At the emitter node : ⎛µ ⎞ ⎛ v ⎞ gπ (v i − v e ) + gm (v i − v e ) + gm (0 − v e ) + gπ (0 − v e ) + go⎜ f v i − v e ⎟ + go ⎜− i − v e ⎟ = 0 ⎝ 4 ⎠ ⎝2 ⎠ ⎛3 g ⎞ ⎜ gm + gπ + o ⎟ ⎛3 g ⎞ v ⎝2 2⎠ 3 ≅ ⎜ gm + gπ − o ⎟v i = (2gm + 2gπ + 2go )v e | e = ⎝2 4⎠ v i (2gm + 2gπ + 2go ) 4 vi , so Rin ≅ 4rπ . If an input is applied to the 4 µ 4 right side instead of the left, the sign changes on the go f v i term, and Rin ≅ rπ . 2 3 The voltage across rπ of the input transistor is 17-42 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.56 RinD = 100kΩ 1MΩ + (10kΩ 10kΩ 40kΩ) = 91.0kΩ | TSC = 0 [ ] 1+ 0 100kΩ = 0.808 | Rin = 91.0kΩ = 50.3 kΩ TOC ≅ gm (10kΩ 10kΩ 40kΩ) 1+ 0.808 100kΩ + 1MΩ RoutD = 10kΩ 10kΩ 40kΩ 1.1MΩ = 4.43kΩ | TSC = 0 1+ 0 100kΩ = 0.808 | Rout = 4.43kΩ = 2.45 kΩ TOC ≅ gm (10kΩ 10kΩ 40kΩ) 1+ 0.808 100kΩ + 1MΩ 17.57 gm 4 (ro 2 ro 4 ) µf 4 RoutD = µ f 4 ro 2 | TOC = 0 | TSC = (gm 3 ro 3 ) ≅ µf 3 ≅ µf 3 1+ gm 4 (ro 2 ro 4 ) 2 + µf 4 1+ µ f 3 = µ f 4 ro2 (µ f 3 + 1) 1+ 0 gm 4 (ro 2 ro 4 ) 1 1+ 0 | TSC = 0 | TOC = µ f 3 ≅ µ f 3 | Rin = ro 3 = 1+ gm 4 (ro 2 ro 4 ) 1+ µ f 3 gm 3 Rout = µ f 4 ro 2 RinD = ro 3 17.58 ⎡ ⎡ ⎤ β o (ro 2 rπ 3 ) ⎤ β o RE βr β2 ⎥ ≅ ro 4 o π 3 = ro4 o Using Wq. (14.28), RoutD = ro ⎢1 + ⎥ = ro 4 ⎢1 + ro 3 µf ⎢⎣ ro 3 + rπ 4 + (ro 2 rπ 3 )⎥⎦ ⎣ Rth + rπ + RE ⎦ TOC = (gm 3 ro 3 ) ro 2 rπ 3 r ≅ (gm 3 ro3 ) π 3 = β o ro 3 + rπ 4 + ro 2 rπ 3 ro 3 (β o + 1)(ro2 rπ 3 ) TSC ≅ (gm 3 ro 3 ) ro3 + rπ 4 + (β o + 1)(ro 2 rπ 3 ) ≅ µ f | Rout β o2 1+ µ f ≅ ro4 ≅ β o ro 4 µ f 1+ β o We cannot exceed the β o ro 4 limit as long as the base current of Q 4 reaches ground! [ ] RinD = ro 3 rπ 4 + (β o + 1)(ro 2 rπ 3 ) ≅ ro 3 β o rπ 3 ≅ ro 3 | TSC = 0 TOC = µ f 3 gm 4 (ro 2 ro 4 ) 1+ gm 4 (ro 2 ro 4 ) ≅ µ f 3 | Rin = ro 3 1+ 0 1 ≅ 1+ µ f 3 gm 3 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-43 17.59 2π x1010 s 2π x10 6 ) ( 10 4 s (a) A(s) = = ⎛ s ⎞ s ⎞ 3 ⎛ (s + 2π x10 )⎜⎝1+ 2π x106 ⎟⎠ (s + 2π x103 )⎜⎝1+ 2π x10 6⎟ ⎠ A(s) represents a band - pass amplifier with two widely - spaced poles Open − loop : Ao = 10 4 or 80 dB (b) | f L = 1 kHz 2π x1010 s (s + 2π x103 )(s + 2π x106 ) Av (s) = 1+ 2π x1010 s (0.01) (s + 2π x103 )(s + 2π x106 ) = | f H = 1 MHz 6.28 x1010 s s 2 + 1.01(2π x10 8 )s + 4π 2 x10 9 Using dominant - root factorization : fH = (c ) 1.01(2π x10 8 ) 2π = 101 MHz, f L = 1 ⎛ 4 π 2 x10 9 ⎞ ⎟ = 9.90 Hz ⎜ 2π ⎜⎝ 1.01(2π x10 8 )⎟⎠ 2π x1010 s (s + 2π x103 )(s + 2π x106 ) Av (s) = 1+ 2π x1010 s (0.025) (s + 2π x103 )(s + 2π x106 ) = 6.28 x1010 s s 2 + 2.51(2π x10 8 )s + 4 π 2 x10 9 Using dominant - root factorization : fH = 17-44 2.51(2π x10 8 ) 2π 1 ⎛ 4 π 2 x10 9 ⎞ ⎟ = 3.98 Hz ⎜ = 251 MHz, f L = 2π ⎜⎝ 2.51(2π x10 8 )⎟⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.60 2x1014 π 2 2π x10 3 )(2π x10 5 ) ( 5x10 5 = (a) A(s) = ⎛ s ⎞ ⎛ s ⎞ s ⎞⎛ s ⎞⎛ 1+ 1+ ⎟ ⎜1+ ⎜1+ 3 ⎟⎜ 5⎟ 3 ⎟⎜ ⎝ 2π x10 ⎠⎝ 2π x10 ⎠ ⎝ 2π x10 ⎠⎝ 2π x10 5 ⎠ A(s) represents a low - pass amplifier with two widely - spaced poles Open − loop : Ao = 5x10 5 = 114dB | f H ≅ f1 = 1000 Hz | fL = 0 (b)A common mistake would be the following : Closed − loop : f H = 1000Hz[1+ 5x10 5 (0.01)]= 5MHz Oops! - This exceeds f 2 = 100 kHz! This is a two - pole low - pass amplifier. 2x1014 π 2 (s + 2π x103 )(s + 2π x105 ) Av (s) = 1+ 2x1014 π 2 (0.01) (s + 2π x103 )(s + 2π x105 ) = 2x1014 π 2 s2 + 1.01(2π x10 5 )s + 2x1012 π 2 Using dominant - root factorization : f1 = 101 kHz, f 2 = 4.95 MHz So the closed - loop values are f H = 101 kHz and f L = 0. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-45 17.61 4 π 2 x1018 s2 2π x10 6 )(2π x10 7 ) ( (a) A(s) = ⎛ s ⎞⎛ s ⎞ 1+ ⎟ (s + 200π )(s + 2000π )⎜1+ 6 ⎟⎜ ⎝ 2π x10 ⎠⎝ 2π x10 7 ⎠ 10 5 s2 ⎛ s ⎞⎛ s ⎞ 1+ ⎟ (s + 200π )(s + 2000π )⎜1+ 6 ⎟⎜ ⎝ 2π x10 ⎠⎝ 2π x10 7 ⎠ A(s) represents a band - pass amplifier with four widely - spaced poles A(s) = Open − loop : Ao = 10 5 or 100 dB (b) | f L ≅ 1 kHz | f H ≅ 1 MHz 4 π 2 x1018 s2 (s + 200π )(s + 2000π )(s + 2π x10 6 )(s + 2π x10 7 ) Av (s) = 1+ 4 π 2 x1018 s2 (0.01) (s + 200π )(s + 2000π )(s + 2π x10 6 )(s + 2π x10 7 ) Using MATLAB : D(s) = s4 + 6.9122x10 7 s3 + 3.9518x1017 s 2 + 2.7288x1018 s + 1.5585x10 21 The closed loop amplifier has complex roots: 10 8 1 −3.45 ± j62.7 = −0.637 ± j9.98 Hz and ( ) ( ) (−0.346 ± j6.28) = (−0.0637 ± j1) x108 Hz 2π 2π Note that the amplifier is stable since all the poles are in the left half plane. See Problem 18.67. (c ) 2π x1010 s (s + 2π x103 )(s + 2π x106 ) Av (s) = 1+ 2π x1010 s (0.025) (s + 2π x103 )(s + 2π x106 ) Using MATLAB : D(s) = s4 + 6.9122x10 7 s3 + 9.909x1016 s2 + 2.7288x1018 s + 1.5585x10 21 The closed loop amplifier has complex roots: 10 8 1 −13.8 ± j124.7 = −2.20 ± j19.9 Hz and ( ) ( ) (−0.346 ± j3.13) = (−0.637 ± j4.98)x10 7 Hz 2π 2π Note that the amplifier is stable since all the poles are in the left half plane. 17-46 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.62 C2 C1 1 µF 1 µF 100 k Ω ii ω1 = 10 k Ω 1MΩ 1M Ω 1 rad = 0.909 10 (100kΩ + 1MΩ) s | ω2 = −6 Separate, widely - spaced, poles → f LA = f 2 = 10 k Ω 1 rad = 58.5 s 10 10kΩ + 25kΩ 10kΩ 1MΩ −6 ( ) 58.5 = 9.31 Hz 2π CGD 3pF + 100 k Ω 1 MΩ C GS R L v1 - 4.15 k Ω gmv1 10 pF 25k Ω||1M Ω||10k Ω||10k Ω ω AH = f HA = 1 = rπoCT ⎡ ⎛ ⎢⎣ ⎝ 4.15kΩ ⎞⎤ ⎠⎥⎦ (100kΩ 1MΩ)⎢10 pF + 3pF ⎜1+ 2mS(4.15kΩ) + 100kΩ 1MΩ ⎟⎥ 1 1 = 46.1 kHz 2π (90.9kΩ)(38.0 pF ) v gs = is (100kΩ 1MΩ) = (90.9kΩ)is A= 1 | v o = −(2x10−3 )v gs (25kΩ 10kΩ 10kΩ 1MΩ) vo = −(2mS )(4.15kΩ)(90.9kΩ) = −7.55x10 5 Ω | y12F = −10−5 S is 1+ Aβ = 1+ (−7.55x10 5 Ω)(−10−6 S)= 1.76 fL = 9.31 = 5.29 Hz 1.76 fH = 46.1kHz(1.76) = 81.0 kHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-47 17.63 C2 1 µF C2 R i Q 1 µF S RF R C 2kΩ R F 100 k Ω R + L v 5kΩ - i 5k Ω o 100 k Ω From the Exercise : gm = 40.3 mS | rπ = 3.72 kΩ | ro = 50.8 kΩ | 1 + Aβ = 2.19 100(0.025) 50 + 1.4 50 + 11.3 = 514kΩ | ro4 = = 613kΩ | rπ 5 = = 2.08kΩ −4 −4 10 10 0.0012 40.3mS Cπ 1 = − 0.75 pF = 12.1pF 2π (500MHz) ro2 = Using the open - circuit time constant approach with C1 = C2 = 1 µF : R1O = 5kΩ + 100kΩ rπ 5kΩ + 100kΩ 3.72kΩ = 8.59kΩ R2O = 5kΩ + 50.8kΩ 2kΩ 100kΩ = 6,89kΩ fL = ⎤ 1 ⎡ 1 fL 1 F + = 19.0 Hz ⎢ ⎥ = 41.6 Hz | f L = 2π ⎣1µF (8.59kΩ) 1µF (6.89kΩ)⎦ 1 + Aβ Q R R S F i R C 2k Ω i 5kΩ + R F 100 k Ω R L 5k Ω 100 k Ω rπo = 3.72kΩ 100kΩ 5kΩ = 2.09kΩ | RL = 50.8kΩ 2kΩ 100kΩ 5kΩ = 1.37kΩ ⎡ 1.37kΩ ⎤ CT = 12.1pF + 0.75 pf ⎢1+ 40.3mS (1.37kΩ) + = 54.8 pF ⎣ 2.09kΩ⎥⎦ 1 1 = = 1.39 MHz | f HF = f H (1+ Aβ ) = 3.04 MHz fH = 2πrπoCT 2π (1.37kΩ)(54.8 pF ) 17-48 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 v o - 17.64 A(s) = 2π x 10 7 s + 2000π | A= ⎛ 2π x 10 7 25 kΩ ⎜ 1kΩ + 25 kΩ + 9.01kΩ ⎝ s + 2000π ⎞ 1.96 kΩ 2.97 x 10 7 = ⎟ ⎠ 1.96 kΩ + 1kΩ s + 2000π 2.97 x 10 7 2.97 x10 7 10.1 s + 2000 π AV (s) = = = 7 6 s 2.97 x 10 s + 2.95 x10 1+ 1+ (0.0990) 2.95 x10 6 s + 2000π 17.65 SAωoH = F Ao ∂ω FH ω FH ∂Ao | ω FH = ω AH (1+ Aβ ) | SAωoH = F 2.95 x10 6 | fH = = 470 kHz 2π Ao Aoβ ω AH β = ≅ +1 ω (1+ Aoβ ) (1+ Aoβ ) A H 10 5 (0.01) ∂ω FH ω ∂Ao = S = 10% = 9.99% A ω FH Ao 1+ 10 5 (0.01) F H o 17.66 (a) At high frequencies with β = 0.01, Aβ = (2 x10 π ) ω + (2πx10 ) 12 Aβ = ω (2 x10 (2 x10 π ) (s + 2000π )(s + 2πx10 ) s(s + 2πx10 ) 14 π 2 )(0.01) 12 ≅ 5 2 5 2 5 2 2 = 1 | Using MATLAB, ω = 4.42 x10 6 ⎛ 4.42 x10 6 ⎞ ∠Aβ = −90 − tan ⎜ = 171.9 o | ΦM = 8.1o 5 ⎟ ⎝ 2πx10 ⎠ −1 (b) At high frequencies with β = 0.025, (5 x10 π ) ω + (2πx10 ) 12 Aβ = ω 2 (2 x10 (5 x10 π ) Aβ = ≅ (s + 2000π )(s + 2πx10 ) s(s + 2πx10 ) 14 π 2 )(0.025) 12 5 2 5 2 5 2 = 1 | Using MATLAB, ω = 7.01x10 6 ⎛ 7.01x10 6 ⎞ ∠Aβ = −90 − tan−1⎜ = 174.9 o | Φ M = 5.1o 5 ⎟ ⎝ 2πx10 ⎠ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-49 17.67 s(2π x1010 )(0.01) 2π x10 8 ≅ (a) At high frequencies with β = 0.01, Aβ = (s + 2000π )(s + 2π x10 6 ) (s + 2πx10 6 ) Aβ = 2π x10 8 ω 2 + (2πx10 ) 6 2 = 1 | ω ≅ 2π x10 8 ⎛ 2π x10 8 ⎞ ∠Aβ = −tan−1⎜ = −89.4 o | ΦM = 90.6 o 6 ⎟ ⎝ 2πx10 ⎠ (b) At high frequencies with β = 0.025, Aβ = 5π x10 8 ω ω 2 + (2πx10 ) 6 2 =1 | Aβ = s(2π x1010 )(0.025) (s + 2000π )(s + 2π x10 6 ) ≅ 5π x10 8 (s + 2πx106 ) ω ≅ 5π x10 8 ⎛ 5π x10 8 ⎞ ∠Aβ = −tan−1⎜ = −89.8 o | ΦM = 90.2 o 6 ⎟ ⎝ 2π x10 ⎠ 17.68 (a) At high frequencies with β = 0.01, Aβ = Aβ ≅ Aβ = s2 (4 π 2 x1018 )(0.01) s 2 (s + 2π x10 6 )(s + 2π x10 7 ) ≅ ω 2 + (2πx10 ) (s + 200π )(s + 2000π )(s + 2π x106 )(s + 2π x107 ) 4π 2 x1016 (s + 2π x106 )(s + 2π x107 ) 4π 2 x1016 6 2 s2 (4 π 2 x1018 )(0.01) ω 2 + (2πx10 ) 6 2 = 1 | Using MATLAB, ω ≅ 6.2673x10 8 8⎞ ⎛ 6.2673x10 8 ⎞ ⎛ −1 6.2673x10 o o ∠Aβ = −tan−1⎜ − tan ⎜ ⎟ ⎟ = −173.7 | Φ M = 6.3 6 7 ⎝ 2πx10 ⎠ ⎝ 2πx10 ⎠ (b) At high frequencies with β = 0.025, Aβ = Aβ ≅ Aβ = s 2 (4 π 2 x1018 )(0.025) s 2 (s + 2π x10 6 )(s + 2π x10 7 ) ≅ ω + (2πx10 ) 6 2 (s + 2π x10 )(s + 2π x10 ) ω + (2πx10 2 (s + 200π )(s + 2000π )(s + 2π x106 )(s + 2π x107 ) π 2 x1017 6 π 2 x1017 2 s2 (4 π 2 x1018 )(0.025) ) 6 2 7 = 1 | Using MATLAB, ω ≅ 9.9246x10 8 8⎞ ⎛ 9.9246x10 8 ⎞ ⎛ −1 9.9246x10 o o ∠Aβ = −tan−1⎜ − tan ⎜ ⎟ ⎟ = −176.0 | ΦM = 4.0 6 7 ⎝ 2πx10 ⎠ ⎝ 2πx10 ⎠ 17-50 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.69 (a) T (s) = 4 x 1019 π 3 β | ∠T ( jω ) = −tan−1 (s + 2π x 10 )(s + 2π x 10 ) 5 2 4 f f − 2tan−1 5 = −180 o 4 10 10 f = −90 o → f = 10 5 Hz. Using this as a starting point 10 5 for iteration, we find f = 110 kHz or ω = 2.2 x 10 5 π For f >> 10 4 , − 2tan−1 4 x 1019 π 3 (b) A(j2.2x10 5 π ) = = 2048 (2.2x10 π ) + (2π x 10 ) [(2.2x10 π ) + (2π x 10 ) ] 2 5 4 2 5 2 5 2 The amplifier will oscillate for closed - loop gains ≤ 2048 (66.2 dB). 17.70 1 sCL ⎛ 10 ⎞ ⎛ 10 7 ⎞ ⎛ 10 7 ⎞ 1 1 T (s) = Aβ = ⎜ = = ⎜ ⎜ ⎟ ⎟ ⎟ ⎝ s + 50 ⎠ R + 1 ⎝ s + 50 ⎠ sCL RO + 1 ⎝ s + 50 ⎠ 500 sCL + 1 O sCL 7 Assume that the unity - gain occurs at ω1 >> 50 : ∠T ( jω1 ) = ∠A + ∠β = −90 o − tan−1 (500ω1CL ) −90 o − tan−1 (500ω1CL ) = −180 o + 60 o | tan−1 (500ω1CL ) = 30 o | 500ω1CL = 0.5774 T ( jω1 ) = 1 | CL = 10 7 ω1 1+ (500ω1CL ) 2 tan(30 o ) 500(8.66 x10 6 ) 17.71 (a) T = Aβ = = 10 7 [ ] ω1 1+ tan(30 o ) 2 = 1 → ω1 = 8.66 x 10 6 = 133 pF ⎛ 1⎞ ⎜ ⎟ | Yes, it is a second - order system and will s + 2x103 π s + 2x10 4 π ⎝ 4 ⎠ 4x1013 π 2 ( )( ) have some phase margin, although Φ M may be vanishingly small. (b) For ω >> 2π x 10 , T (jω ) ≈ 4 ( ) ∠T j9.935x106 = − tan −1 1x1013 π 2 ω 2 and T (jω ) = 1 for ω = 9.935x106 rad s 6 9.935x10 9.935x106 − tan −1 = 179.6 o → Φ M = 0.4 o | A very 2000π 20000π small phase margin. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-51 17.72 (a) T = Aβ = ⎛ 1⎞ 2x1014 π 2 ⎜ ⎟ | Yes, it is a second - order system and will 3 5 (s + 2x10 π )(s + 2x10 π )⎝ 5 ⎠ have some phase margin, although Φ M may be vanishingly small. (b) For ω >> 2π x 10 5 , T ( jω ) ≈ ∠T (j1.987x10 7 )= −tan−1 4 x1013 π 2 ω 2 and T ( jω ) = 1 for ω = 1.987x10 7 rad s 7 1.987x10 1.987x10 7 − tan−1 = 178.2 o → ΦM = 1.83o | A very 5 2000π 2x10 π small phase margin. 17.73 (a) The following command line will generate the complete bode plot: w=logspace(3,8,400); bode((2e14*pi^2/5),conv([1 2000*pi],[1 2e5*pi]),w) The following command line will generate the bode plot between 107 and 108rad/s: w=logspace(7,8,100); bode((2e14*pi^2/5),conv([1 2000*pi],[1 2e5*pi]),w) The second plot agrees with the results calculated in the previous problem. 20 Gain dB 10 0 -10 -20 -30 10 7 Frequency (rad/sec) 10 8 -176 Phase deg -177 -178 -179 -180 10 7 Frequency (rad/sec) 10 8 (b) w=logspace(7,8,100); bode((2e14*pi^2),conv([1 2000*pi],[1 2e5*pi]),w) yields a phase margin of only 0.75 degrees 17-52 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.74 C vi R A(s) + β= R R+ 1 sC = 2π x 10 6 sRC 2π x 10 6 sRC | T= | For ωRC >> 1, T ≅ sRC + 1 s + 20π (sRC + 1) s + 20π and T = 1 for ω = 2π x 10 6. Given RC = 10 -8 (10 5 )= 10−3 , β = s s + 1000 6 2π x 10 6 −1 2π x 10 ∠T = 90 − tan − tan = −90.0 o | ΦM = 90.0 o 20π 1000 o −1 17.75 s10 5 (10−8 ) sRC s β= = = = 5 −8 1 sRC + 1 s10 (10 )+ 1 s +1000 R+ sC 10 5 4 π 2 x 1013 A(s) = = ⎛ ⎞ (s + 2000π )(s + 200000π ) s s ⎞⎛ ⎜1 + ⎟⎜1 + ⎟ ⎝ 2000π ⎠⎝ 200000π ⎠ R T= s 4 π 2 x 1013 4 π 2 x 1013 | At high frequencies, T ≅ s2 (s + 2000π )(s + 200000π ) (s + 1000) and the integrator will have a positive phase margin, although ΦM may be very small. For ω >> 2π x 10 5, T ( jω1) ≈ ∠T = 90 o − tan−1 7 4 π 2 x 1013 ω 2 1 = 1 ⇒ ω = 1.987 x 10 7 rad >> 2π x 10 5 s 1.987 x 10 1.987 x 10 7 1.987 x 10 7 − tan−1 − tan−1 2000π 200000π 1000 | ΦM = 1.83o ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-53 17.76 Gain dB 100 50 0 -50 101 0 102 103 104 10 5 106 102 103 104 10 5 106 Phase deg -50 -100 -150 -200 101 Frequency (rad/sec) (a) β = R1 1 sCC R1 + 1 R2 + sCC R2 For CC = R1 R1 + R2 sCC R2 + 1 = R1 sCC R2 + 1 R1 + R2 sCC (R1 R2 )+ 1 2x1011 π 2 1 = 0, T = (s + 200π )(s + 20000π ) 21 The graphs above were generated using bode(2e11*pi^2/21,[1 2.02e4*pi 4e6*pi^2]) Blowing up the last decade: w=linspace(1e5,1e6); bode(2e11*pi^2/21,[1 2.02e4*pi 4e6*pi^2],w) and the phase margin is approximately 12o Gain dB 20 0 -20 Phase deg -40 105 -140 Frequency (rad/sec) 106 Frequency (rad/sec) 106 -150 -160 -170 -180 105 Setting the zero to cancel the second pole, 17-54 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 1 R1 sCC R2 + 1 CC R2 β (s) = = 1 R1 + R2 sCC (R1 R2 )+ 1 s + CC (R1 R2 ) s+ T= 2x1011 π 2 2x1011 π 2 (s + 20000π ) = (s + 200π )(s + 20000π ) s + 1.319x10 6 s2 + 1.320x10 6 s + 8.288x10 6 Using MATLAB: bode(2e11*pi^2,[1 1.320e6 8.288e8]) and then w=linspace(1e6,1e7); bode(2e11*pi^2,[1 1.320e6 8.288e8],w) Gain dB 20 0 -20 -40 106 Frequency (rad/sec) 107 Frequency (rad/sec) 107 Phase deg -120 -140 -160 -180 106 The phase margin is now approximately 50o 17.77 num=4e19*pi^3; p=conv([1 2e5*pi],[1 2e5*pi]); den=conv([1 2e4*pi],p]; bode(num,den) 5 Results: Frequency = 6.9 x10 rad/s and approximately 66 dB which agree with the hand calculations in Problem 17.69. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-55 17.78 Bode Diagrams 120 100 80 60 40 20 0 -50 -100 -150 -200 3 10 10 4 10 5 10 6 10 7 Frequency (rad/sec) Expanded view: Bode Diagrams 70 60 50 40 30 20 -145 -150 -155 -160 -165 -170 -175 -180 10 6 10 7 Frequency (rad/sec) For a gain of 100 (40 dB), the phase margin is approximately 8o. For a gain of 40 (32 dB), the phase margin is approximately 5o. The gain margin is infinite in both cases since the phase shift never reaches 180o. These values agree with the calculations in Problem 17.59. (b) The amplifier will not oscillate. 17-56 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.79 Bode Diagrams 80 70 60 50 40 100 50 0 -50 -100 2 10 10 3 10 4 10 5 10 6 10 7 10 8 Frequency (rad/sec) The phase shift ranges from +90o at low frequencies to –90o at high frequencies. The phase margin for both gains of 100 and 40 is 90o at the high frequency intersection and 270o at the low end. These values agree with the calculations in Problem 17.60. (b) The amplifier will not oscillate. Expanded view at high frequencies: Bode Diagrams 80 70 60 50 40 30 20 10 0 -20 -40 -60 -80 -100 6 10 10 7 10 8 10 9 10 10 Frequency (rad/sec) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-57 17.80 Bode Diagrams 100 80 60 40 20 0 200 100 0 -100 -200 1 10 10 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 Frequency (rad/sec) Bode Diagrams 80 60 40 20 0 -20 -140 -150 -160 -170 -180 8 10 10 9 10 10 Frequency (rad/sec) The phase margin is approximately 6o and 4o for gains of 40 dB and 32 dB respectively. The gain margin is infinite in both cases. These values agree with the calculations in Problem 17.61. (b) The amplifier will not oscillate. 17-58 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.81 num=2e11*pi^2 den=conv([1 200*pi],[1 20000*pi]); bode(num/100,den) w=logspace(5,6,100); bode(num/100,den,w) Results: Yes, the amplifier is stable with a phase margin of approximately 26o. Bode Diagrams 60 40 20 0 -20 -40 0 -50 -100 -150 -200 2 10 10 3 10 4 10 5 10 6 Frequency (rad/sec) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-59 17.82 Aoω o 2π x 10 6 ωT ωT s + ωo Av (s) = = ≅ = Aω s + (1+ Ao )ω o s + ωT s + 2π x 10 6 1+ o o s + ωo 5x10 4 s s2 + 7x10 4 s + 5x10 8 1011 πs T (s) = Av (s)β (s) = (s + 2π x 106 )(s2 + 7x104 s + 5x108 ) From problem 18.45 : β (s) = Using MATLAB: num=[pi*1e11 0] den=conv([1 3e5 1e10],[1 5e6]) bode(num,den) It is also instructive to use: nyquist(num,den) One finds that |T(jω)| < 1 for all ω, so the phase margin is undefined. The filter is stable. Note that this is a positive feedback system so the point of interest is +1. The gain of the filter is approximately -3 dB. So the filter has a gain margin of 3 dB. Bode Diagrams 0 -20 -40 -60 -80 -100 100 50 0 -50 -100 -150 -200 2 10 10 3 10 4 10 5 10 6 10 7 10 8 Frequency (rad/sec) 17-60 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.83 ⎛ 10 7 ⎞⎛ ⎞ 10 5 s 1012 s = T (s) = K (s)β (s) = ⎜ 6 ⎟⎜ 2 5 10 ⎟ 6 2 5 10 ⎝ s + 5 x 10 ⎠⎝ s + 3x10 s + 10 ⎠ (s + 5 x 10 )(s + 3x10 s + 10 ) Using MATLAB: num=[1e12 0] den=conv([1 3e5 1e10],[1 5e6]) bode(num,den) It is also instructive to use: nyquist(num,den) One finds that |T(jω)| < 1 for all ω, so the phase margin is undefined. The filter is stable. Note that this is a positive feedback system so the point of interest is +1. The gain of the filter is approximately -3 dB. So the filter has a gain margin of 3 dB. Bode Diagrams 0 -20 -40 -60 -80 -100 100 50 0 -50 -100 -150 -200 2 10 10 3 10 4 10 5 10 6 10 7 10 8 Frequency (rad/sec) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-61 17.84 sRC s 2π x 10 6 s = | T= sRC + 1 s + 1000 (s + 20π )(s + 1000) Using MATLAB: num=[2e6*pi 0]; den=conv([1 20*pi],[1 1000]); w=logspace(0,8,400); bode(num,den,w) The phase margin is 90o which agrees with Problem 17.74. β= Bode Diagrams 80 60 40 20 0 -20 -40 100 50 0 -50 -100 0 10 10 2 10 4 10 6 10 8 Frequency (rad/sec) 17-62 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.85 β= sRC s 10 5 4 π 2 x 1013 = | A(s) = = ⎞ (s + 2000π )(s + 200000π ) ⎛ s s ⎞⎛ sRC + 1 s +1000 ⎟⎜1 + ⎟ ⎜1 + ⎝ 2000π ⎠⎝ 200000π ⎠ 4 π 2 x 1013 s T= (s + 2000π )(s + 200000π )(s + 1000) Using MATLAB: num=[4e13*pi^2 0]; den=conv([1 1000],conv([1 2000*pi],[1 200000*pi])); w=logspace(7,8,100); bode(num,den,w) The phase margin is 1.8o which agrees with Problem 17.75. Bode Diagrams 20 10 0 -10 -20 -30 -176 -177 -178 -179 -180 7 10 10 8 Frequency (rad/sec) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-63 17.86 R1 R1 1 1 sCS R1 + 1 β (s) = = = −6 R1 + R2 R1 + R2 sCS (R1 R2 )+ 1 9.30(1.89x10 s + 1) sCS R1 + 1 10 7 T (s) = Av (s)β (s) s + 50 5.69x1011 For ω >> 50, T ( jω ) ≅ → T ( jω ) = 1 for ω = 6.68x10 5 2 ω ω 2 + (5.29x10 5 ) β (s) = 5.69x10 4 s + 5.29x10 5 ΦM = 180 − tan−1 Av (s) = 6.68x10 5 6.68x10 5 − tan−1 = 38.4 o 5 50 5.29x10 17.87 2(0.001)(125x10−6 ) gm1 = = 10.6 MHz | (a) fT = 2πCC 2π (7.5x10−12 ) Since I 2 > I1, the slew rate I1 250x10−6 V V is approximately symmetrical. | SR = = = 33.3x10 6 = 33.3 −12 s CC 7.5x10 µs 2(0.001)(250x10−6 ) gm1 = = 11.3 MHz | Since I 2 > I1, the slew rate (b) fT = 2πCC 2π (10−11 ) is asymmetrical. | SR+ = I1 500µA V 250µA V = = 50 | SR− = = 25 10 pF CC 10 pF µs µs 17.88 2(0.001)(250x10−6 ) gm1 fT = = = 11.3 MHz | Since I 2 > I1, the slew rate 2πCC 2π (10−11 ) is symmetrical. | SR = 17-64 V I1 500x10−6 V = = 50x10 6 = 50 −11 CC 10 µs s ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.89 *Problem 17.89 - CMOS Op-amp VDD 8 0 DC 10 VSS 9 0 -10 I1 1 9 250U I2 6 9 500U I3 7 9 2M V1 4 0 DC -2.23M AC 0.5 V2 2 0 AC -0.5 M1 3 2 1 1 NFET W=20U L=1U M2 5 4 1 1 NFET W=20U L=1U M3 3 3 8 8 PFET W=40U L=1U M4 5 3 8 8 PFET W=40U L=1U M5 6 5 8 8 PFET W=160U L=1U M6 8 6 7 7 NFET W=60U L=1U CC 5 6 7.5PF *CC 5 10 7.5PF *RZ 10 6 1K .MODEL NFET NMOS KP=2.5E-5 VTO=0.70 GAMMA=0.5 +LAMBDA=0.05 TOX=20N +CGSO=4E-9 CGDO=4E-9 CJ=2.0E-4 CJSW=5.0E-10 .MODEL PFET PMOS KP=1.0E-5 VTO=-0.70 GAMMA=0.75 +LAMBDA=0.05 TOX=20N +CGSO=4E-9 CGDO=4E-9 CJ=2.0E-4 CJSW=5.0E-10 .OP .TF V(7) V1 .AC DEC 100 1 20MEG .PRINT AC VM(7) VP(7) .PROBE .END Results: 8.1 MHz, -110 degrees; 8.0 MHz, -92 degrees 17.90 gm 40IC1 = 2πCC 2πCC I1 2 40(25µA) = 13.3 MHz 2π (12 pF ) (a) fT = SR = I1 25µA MV V = = 2.09 = 2.09 since I2 > I1. The slew rate is symmetrical. s CC 12 pF µs (b) fT = | IC1 = | fT = 40(100µA) I 100µA MV V = 53.1 MHz | SR = 1 = = 8.33 = 8.33 s 2π (12 pF ) CC 12 pF µs ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-65 17.91 40(250µA) I1 | fT = = 159 MHz 2 2π (10 pF ) fT = gm 40IC1 = 2πCC 2πCC SR = I1 500µA MV V = = 50 = 50 since I2 > I1 . The slew rate is symmetrical. s CC 10 pF µs 17.92 SR = | IC1 = V I1 40µA V = = 8x10 6 = 8 s CC 5 pF µs *Problems 17.92 - Bipolar Op-amp VCC 8 0 DC 10 VEE 9 0 -10 I1 1 9 40U I2 6 9 400U I3 7 9 500U V1 4 0 DC 0 PWL (0 0 5U 0 5.1U 5 10U 5 10.2U -5 15U -5 15.2U 5 20U 5) VF 2 7 DC -0.0045 Q1 3 2 1 NBJT Q2 5 4 1 NBJT Q3 3 10 8 PBJT Q4 5 10 8 PBJT Q11 0 3 10 PBJT Q5 6 5 8 PBJT Q6 8 6 7 NBJT CC 5 6 5PF .MODEL NBJT NPN BF=100 IS=1FA VAF=80 RB=250 TF=0.65NS CJC=2PF .MODEL PBJT PNP BF=100 IS=1FA VAF=80 RB=250 TF=0.65NS CJC=2PF .OP .TRAN .05U 20U .PROBE V(4) V(5) V(6) V(7) .END Results: -8V/µs, +6V/µs 17.93 SR = V I1 100µA V = = 12.5x10 6 = 12.5 CC 8 pF µs s 17-66 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.94 fT = gm 40IC1 = 2πCC 2πCC | IC 1 = I1 2 | fT = 40(50µA) = 21.2 MHz 2π (15 pF ) *Problem 17.94 - Bipolar Op-amp VCC 8 0 DC 10 VEE 9 0 -10 I1 1 9 100U I2 6 9 500U I3 7 9 500U V1 4 0 DC 2.10M AC 0.5 V2 2 0 DC 0 AC -0.5 Q1 3 2 1 NBJT Q2 5 4 1 NBJT Q3 3 10 8 PBJT Q4 5 10 8 PBJT Q11 0 3 10 PBJT Q5 6 5 8 PBJT Q6 8 6 7 NBJT CC 5 6 15PF .MODEL NBJT NPN BF=100 IS=1FA VAF=80 RB=250 TF=0.65NS CJC=2PF .MODEL PBJT PNP BF=100 IS=1FA VAF=80 RB=250 TF=0.65NS CJC=2PF .OP .TF V(7) V1 .AC DEC 100 1 20MEG .PRINT AC VM(7) VP(7) .PROBE .END Spice Results: (a) 16.2MHz (b) 16.3 MHz - 15 pF does not represent the effective value of CC. ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-67 17.95 (a) The SPICE results agree with those given in Ex. 11.10: Ao = 67.2 dB, dB, fH = 4.5 kHz, fT = 10.5 MHz, and with a phase margin of 74o 100 -0 -100 -200 -300 1.0Hz DB(V(R3:2)) 10Hz P(V(R3:2)) 100Hz 1.0KHz 10KHz 100KHz 1.0MHz 10MHz 100MHz Frequency (b) Note, λ should be 0.02V-1 for the MOSFETs. (b) The SPICE results give Ao = 86.5 dB, fT = 8.5 MHz and with a phase margin of 68.4o. SR+ = 17.6 V/µsec, and SR- = -15.6 V/µsec. 12V 8V 4V 0V -4V -8V -12V 0s 1us 2us 3us 4us 5us 6us 7us V(M3:d) Time 17-68 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 8us 9us 10us 17.96 ⎛ 2R ⎞ Vo1 1 =− Vo 2 = ⎜1+ ⎟V = 2V+ ⎝ 2R ⎠ + sRC Vo 2 G (V+ − Vo1) + sCV+ + (V+ − Vo2 )GF = 0 Combining these yields 2 V G 1 and T (s) = Av1 Av 2 = Av 2 = o 2 = ⎞ ⎛G ⎛ Vo1 1 R⎞ sC + ⎜ − GF ⎟ sRC⎜ sRC + − ⎟ ⎠ ⎝2 2 RF ⎠ ⎝ Av1 = ∠T ( jω o ) = 0 → RF = 2R and T ( jω o ) = 1 → ω o = 1 RC 17.97 Define V1 as the output of the inverting amplifier and V2 as the output of the right - hand non - inverting amplifier. ⎛ ⎛ ⎞ ⎞ ⎞ ⎛ ⎜ ⎜ ⎟ R ⎟⎛ R2 ⎞ R Z R sCR R V1 = −V2 2 = −V2 = −V2 | V2 = V1⎜ 1+ 2 ⎟⎜ 1+ ⎜ ⎟ 1 ⎟⎜⎝ R1 ⎟⎠ 1 1 ⎝ R1 ⎠ Z1 SCR + 1 ⎜R+ ⎜R+ ⎟ ⎟ R+ ⎝ ⎝ sC ⎠ sC sC ⎠ 2 2 ⎡ ⎛ ⎛ jωCR ⎞ 3 ⎛ R2 ⎞ ⎞ 3 ⎛ R2 ⎞ ⎤ sCR V2⎢1+ ⎜ ⎟ ⎜1+ ⎟ ⎥ = 0 | ⎜ ⎟ ⎜1+ ⎟ = −1 ⎝ jωCR + 1⎠ ⎝ R1 ⎠ ⎢⎣ ⎝ SCR + 1⎠ ⎝ R1 ⎠ ⎥⎦ 3[90 o − tan−1 (ωCR)]= 180 o | tan−1 (ωCR) = 30 o | ωCR = tan(30 o )= 0.5774 3 ⎤ 2⎡ ⎞3 ⎛ o ⎛ R2 ⎞ 2⎛ R2 ⎞ ⎢ tan(30 ) ⎥ R ωCR ⎜ ⎟ = ⎜1+ ⎟ = 1 → 2 = 8 −1 = 1.83 ⎜1+ ⎟ 2 2 o ⎥ ⎢ ⎜ ⎟ R1 ⎝ R1 ⎠ ⎝ 1+ (ωCR) ⎠ ⎝ R1 ⎠ 1+ tan (30 ) ⎦ ⎣ 17.98 10 k Ω 10 k Ω 15 k Ω 6.2 k Ω fo = 1 2π (5kΩ)(500 pF ) = 63.7 kHz | vO = 3(0.7V ) = 6.85 V ⎛ 15kΩ ⎞⎛ 10kΩ ⎞ 10kΩ ⎜2 − ⎟⎜1+ ⎟− ⎝ 10kΩ ⎠⎝ 6.2kΩ ⎠ 10kΩ ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-69 17.99 *Problem 17.99 - Wien-Bridge Oscillator C1 1 0 500PF IC=1 RA 1 0 5K C2 1 2 500PF RB 2 3 5K E1 3 0 1 6 1E6 R1 6 0 10K R2 5 6 15K R3 3 5 6.2K R4 4 5 10K D1 3 4 DMOD D2 4 3 DMOD .MODEL DMOD D .TRAN 10U 10M UIC .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END Results: f = 60.0 kHz, amplitude = 6.8 V 17.100 - + v 47 k Ω i 68 k Ω 0.7 V B 15 k Ω i v O + Using Eq. (17.135), f o = 1 ( ) 2π 3 (5000) 10−9 = 18.4 kHz Using Eq. (17.136), the total feedback resistance should be R1 = 12R = 60kΩ. The current in R1 is I = VB = I (47kΩ) = VO V V = O = O . The voltage at VB is R1 12R 60kΩ 47kΩ V V − VB VO − 0.7 − VB VO | In the diode network, I = O = O + 60kΩ 15kΩ 68kΩ 60kΩ 13 13 VO VO 60 + 60 − VO = 0.7 → V = 10.7 V O 15kΩ 68kΩ 60kΩ 68kΩ 17-70 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.101 *Problem 17.101 - Phase Shift Oscillator C1 1 6 1000PF IC=1 RA 1 0 5K C2 1 2 1000PF RB 2 0 5K C3 2 3 1000PF E1 3 0 0 6 1E6 R2 6 5 47K R3 5 3 15K R4 5 4 68K D1 3 4 DMOD D2 4 3 DMOD .MODEL DMOD D .TRAN 10U 20M UIC .PROBE V(1) V(2) V(3) V(4) V(5) V(6) .END Results: f = 17.5 kHz, amplitude = 11.5 V ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-71 17.102 Note that the presence of rπ makes the analysis more complex than the FET case. C4 is a coupling capacitor, and its impedance is neglected in the analysis. C5 = C1 + Cπ. However, the effect of rπ can usually be neglected in the fo calculation as shown below. ⎡ 1 ⎢s(C5 + Cµ )+ gπ + sL ⎢ − sC + g + g ⎣ ( 5 m π) ⎤⎡ ⎤ ⎡ ⎤ ⎥⎢Vb ⎥ = ⎢0⎥ s(C2 + C5 ) + gm + gπ + GE ⎥⎦⎣Ve ⎦ ⎣0⎦ −(sC5 + gπ ) ∆ (s) = s2 [C5C2 + Cµ (C2 + C5 )]+ s[C2 gπ + Cµ (gm + gπ + GE ) + C5GE ] + gm + gπ + GE (C + C5 ) + gπ GE + 2 sL L vb + g m (v b -v e ) v C 1 Cπ - rπ L ve Cµ RE C2 ∆ ( jω o ) = 0 | ω o2 = ⎤ ⎤ 1 ⎡1 1 ⎡1 1 gm CC ⎢ + ⎥= ⎢ + ⎥ | CTC = Cµ + 2 5 CTC ⎣ L rπ RE (C2 + C5 )⎦ CTC ⎣ L β o RE (C2 + C5 )⎦ C 2 + C5 gm + gπ + GE ω oL ⎤ ⎤ ⎡ ⎡ ⎥ ⎥ ⎢ ⎢ C2 C5 C2 C5 ⎥ = 1 | ω o2 L⎢Cµ + ⎥ =1 ω o2 L⎢Cµ + + + rπ RE ⎥ βo gm RE ⎥ ⎢ ⎢ β o + 1+ 1+ gm RE + β o + 1+ 1+ gm RE + ⎢⎣ ⎢⎣ RE rπ ⎥⎦ gm RE β o ⎥⎦ ⎤ 100 pF (20 pF ) 1 ⎡ 1 10mS = 16.7 pF | ω o2 = + ⎢ ⎥ (a) CTC = 100 pF + 20 pF 16.7 pF ⎣5µH 100(1kΩ)(100 pF + 20 pF )⎦ 1 ω o2 = [2x105 + 833]→ f o = 17.5 MHz 16.7 pF 1 1 Note that the correction term is negligible : ω o ≅ (b) CTC = 1 1 1 LCTC + + C 2 C5 C3 ω o [C2 gπ + Cµ (gm + gπ + GE ) + C5GE ]= 17-72 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 1 1 1 = 3.85 pF | f o ≅ = = 36.3 MHz 1 1 1 2 π LC π 5 µ H 3.85 pF 2 ( ) ( ) TC + + 100 pF 20 pF 5 pF 1 1 max CTC = = 12.5 pF | f o ≅ = 20.1 MHz 1 1 1 π 5 µ H 12.5 pF 2 ( ) ( ) + + 100 pF 20 pF 50 pF ⎤ ⎤ ⎡ ⎡ ⎥ 1 ⎢ ⎥ ⎢ C2 C5 C2 C5 ⎥≅ ⎥=1 ⎢ + + (c ) ω o2 L⎢ βo gm RE ⎥ CTC ⎢ gm RE ⎥ ⎢β + 1+ β o 1+ g R + β + 1+ 1+ g R + m E m E ⎢⎣ o ⎢⎣ o gm RE β o ⎥⎦ gm RE β o ⎥⎦ ⎤ ⎡ ⎥ ⎢ 1 ⎢ 100 pF 20 pF ⎥ = 1 | MATLAB yields gm = 0.211 mS + gm (1kΩ) ⎥ 16.7 pF ⎢101+ 100 1+ gm (1kΩ) + ⎢⎣ gm (1kΩ) 100 ⎥⎦ min = CTC IC = (0.211mS)(0.025V ) = 5.28 µA 17.103 Assuming the effect of rπ is negligible: (a) f o ≅ CEQ = (b) Cπ fo ≅ 1 2π 1 CEQ L | CEQ = 1 1 + C4 C + µ | Cπ = 1 1 1 1 + C1 + Cπ C2 1 1 + 0.01uF 3pF + = 1 2π 40(5mA) − 3pF = 60.7 pF 10 9 π = 47.4 pF | f o ≅ 1 1 1 1 + (20 + 60.7)pF 100 pF 40(10mA) − 3pF = 124 pF | CEQ = 10 9 π 1 2π 1 = 5.17MHz 47.4 pF (20µH ) 1 1 + 0.01uF 3pF + = 61.6 pF 1 1 1 1 + 20 pF + 124 pF 100 pF 1 = 4.53MHz 61.6 pF (20µH ) ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-73 17.104 CTC = 1 1 1 = = 21.1pF | CTC = 2 2 1 1 ω o L 4x10 7 π (3µH ) + C1 C2 ( ) | gmR ≥ C1 2I D R C → ≥ 1 VGS − VTN C2 C2 2 2 Kn 1.25mA VGS − VTN ) = VGS + 4) | − 4 ≤ VGS Suppose we pick VGS = -2 V to provide ( ( 2 2 2 2V = 800Ω → 820 Ω good value of g m : VGS = −2V → I D = 0.625mA(−2 + 4) = 2.50mA | R = 2.5mA 2(2.5mA)820Ω 2I D R C1 ≤ = = 2.05 | C1 ≤ 2.05C2 | Select C1 ≅ C2 ≅ 42 pF | Choosing C2 VGS − VTN −2 − (−4) ID = C1 = 47 pF from Appendix C, C2 = If 47pF and 39pF are used : f o = 1 1 1 − 21.1pF 47 pF = 38.3 pF which is close to 39 pF. 1 2π (21.3 pF )(3µH ) = 19.9 MHz In order to obtain an exact frequency of oscillation, a 33-pF capacitor in parallel with a small variable capacitor could be used. Note that including the FET capacitances would modify the design values. 17.105 L C CGD C2 C3 C1 L C GS CGS C 1 1 = 4 pF + = 31.27 pF 1 1 1 1 + + C2 C1 + C3 + CGS 50 pF 50 pF + 0 + 10 pF 1 1 fo = = = 9.00MHz −5 2π LCTC 2π (10 H )(31.27x10−12 F ) CTC = CGD + gm ro ≥ 17-74 2 CGD C1 + C3 + CGS 50 pF + 0 + 10 pF = = 1.20 which is easily met. 50 pF C2 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 1 C 3 17.106 (a) CTC = CGD + fo = 1 1 1 + C2 C1 + C3 + CGS 1 = 2π LCTC 2π max | CTC = 4 pF + 1 (10µH )(32.3pF ) 1 = 32.3pF 1 1 + 50 pF 50 pF + 5 pF + 10 pF = 8.87 MHz 1 1 = 38.4 pF | f o = = 8.12 MHz 1 1 2π (10µH )(38.4 pF ) + 50 pF 50 pF + 50 pF + 10 pF C +C +C 50 pF + 5 pF + 10 pF = 1.30 and (b) gm ro ≥ 1 3 GS | gm ro ≥ C2 50 pF min CTC = 4 pF + gm ro ≥ 50 pF + 50 pF + 10 pF = 2.20 | ∴ gm ro ≥ 2.20 which is easily met. 50 pF 17.107 (a) CD = C jo 1+ CD = f omin VTUNE | CD = φj 20 pF 1 = 10.7 pF | CTC = = 40.0 pF 1 1 2V + 1+ 75 pF + 10.7 pF 75 pF 0.8V 20 pF 1 = 3.92 pF | CTC = = 38.5 pF 1 1 20V + 1+ 75 pF + 3.92 pF 75 pF 0.8V 1 1 = = 7.96 MHz | f omax = = 8.11 MHz 2π (10µH )(40.0 pF ) 2π (10µH )(38.5 pF ) (b) In this circuit, R = ro : µ f = gm ro ≥ C1 + CD C2 | µf ≥ 78.9 pF = 1.05 75 pF ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-75 17.108 CTC = 1 1 1 + 470 pF 220 pF The required g m R ≥ = 150 pF | f o = 1 2π (10µH )(150 pF ) = 4.11 MHz C2 220 pF = = 0.468 is met : C1 470 pF 2 2 Kn 1.25mA VGS − VTN ) = VGS + 4) and VGS = −820I D → VGS = −2.016V , I D = 2.46mA ( ( 2 2 2(2.46mA)(820Ω) 2I D R ≅ = 1.02 gm R = VGS − VTN −2.02 − (−4) This analysis is borne out by the SPICE simulation below. VDD 3 0 DC 10 R 1 0 820 C1 1 0 470PF IC=2 C2 2 1 220PF IC=0 *C1 1 0 220PF IC=2 *C2 2 1 470PF IC=0 L 2 0 10UH M1 3 2 1 NFET .MODEL NFET NMOS VTO=-4 KP=1.25MA .OP .TRAN 10N 30U UIC .PROBE .END C 470 pF (b) For this case, the required g m R ≥ C2 = 220 pF = 2.14 is not met, 1 ID = and the circuit fails to oscillate. SPICE simulation confirms that the circuit does not oscillate. 17-76 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.109 CTC = 3pF + 1 = 30.3pF | f o = 1 1 2π + 50 pF + 10 pF 50 pF 1 (10µH )(30.3pF ) = 9.15 MHz *Problem 17.109 NMOS Colpitts Oscillator VDD 3 0 DC 12 LRFC 3 2 20MH C1 1 0 50PF C2 2 0 50PF L 2 1 10UH M1 2 1 0 0 NFET CGS 1 0 10PF CGD 1 2 4PF .MODEL NFET NMOS VTO=1 KP=10MA LAMBDA=0.02 .OP .TRAN 50N 40U UIC .PROBE .END Results: f = 7.5 MHz, amplitude = 80 V peak-peak. There is little to set the amplitude in this circuit, and the frequency of oscillation is significantly in error. Also, µf of the transistor greatly exceeds the gain required for oscillation and the waveform at the drain is highly nonlinear. The voltage at the gate is filtered by the LC network and is more sinusoidal in character. A diode from ground to gate could be employed to help limit the amplitude of the oscillation. 17.110 fo = 2π 1 (10µH + 10µH )(20 pF ) = 7.96 MHz ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-77 17.111 1 1 20 pF | CTC = | C = 220 pF | CD = | L = L1 + L2 = 20µH 1 1 2π LCTC V + 1+ TUNE C CD 0.8V 20 pF 1 (a) CD = = 10.7 pF | CTC = = 10.2 pF 1 1 2V + 1+ 220 pF 10.7 pF 0.8V fo = fo = 1 2π 20µH (10.2 pF ) = 11.1 MHz 20 pF 1 = 3.92 pF | CTC = = 3.85 pF 1 1 20V + 1+ 220PF 3.92 pF 0.8V 1 L fo = = 18.1 MHz (b) µ f ≥ 1 = 1.00 L2 2π 20µH (3.85 pF ) CD = 17.112 ωS = 1 RQ | L= ωS LCS (a) L = 40(25000) 1 1 = 15.915 mH | CS = 2 = = 15.916 fF 2 7 7 2x10 π ω S L (2x10 π ) 15.915mH 1 1 = 15.890 fF | f P = = 10.008 MHz 1 1 π 15.915mH 15.890 fF 2 ( ) + 15.915 fF 10 pF 1 1 (c) CP = = 15.907 fF | f P = = 10.003 MHz 1 1 2π 15.915mH (15.907 fF ) + 15.915 fF 32 pF (b) CP = 17-78 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17.113 C2 15 mH 5pF C1 20fF (a) CTC = fP = 40(2.14mA) 5 − 0.7 = 2.14mA | Cπ = − 5 pF = 49.5 pF 100kΩ + 101(1kΩ) 2π (2.5x10 8 Hz) 1 1 + 20 fF 5 pF + 1 1 + 100 pF 470 pF + 49.5 pF 2π 15mH (19.996 fF ) max CTC = = 19.996 fF 1 1 17.114 max CTC 100pF 1 1 = 19.995 fF | f P = = 9.190 MHz 1 1 1 2π 15mH (19.995 fF ) + + 20 fF 470 pF 100 pF (b) IC = 100 CTC = Cπ 470pF Cµ 1 = 9.190 MHz = 19.60 fF | f P = 1 = 9.28 MHz 1 1 1 1 2 π 15mH 19.60 fF ( ) + + + 20 fF 1pF 100 pF 470 pF 1 1 = = 19.98 fF | f P = = 9.19 MHz 1 1 1 1 2 π 15mH 19.98 fF ( ) + + + 20 fF 35 pF 100 pF 470 pF ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 17-79 17.115 *Problem 17.115 BJT Colpitts Crystal Oscillator VCC 1 0 DC 5 VEE 4 0 DC -5 Q1 1 2 3 NBJT RE 3 4 1K RB 2 0 100K C1 3 0 100PF C2 2 3 470PF LC 2 6 15M CC 6 5 20FF IC=5 RC 5 0 50 .MODEL NBJT NPN BF=100 VA=50 TF=1N CJC=5PF .OP .TRAN 2N 20U UIC .PROBE .END In the period of time used in the simulation results, node 6 at the interior of the crystal oscillates vigorously, but the oscillation is not coupled well to the other nodes. 17-80 ©Richard C. Jaeger and Travis N. Blalock - 3/10/07 Microelectronic Circuit Design Fourth Edition - Part I Solutions to Exercises CHAPTER 1 Page 11 5.12V 5.12V VLSB = 10 = = 5.00 mV 2 bits 1024bits 11000100012 = 29 + 28 + 2 4 + 20 = 78510 or € € ( 5.12V = 2.560V 2 VO = 785(5.00mV ) = 3.925 V VMSB = ) VO = 2−1 + 2−2 + 2−6 + 2−10 5.12V = 3.925 V Page 12 5.0V 5.00V 1.2V VLSB = 8 = = 19.53 mV N= 256bits = 61.44bits 5.00V 2 bits 256bits 61 = 32 + 16 + 8 + 4 + 1 = 25 + 2 4 + 23 + 22 + 20 = 001111012 Page 12 The dc component is VA = 4V. The signal consists of the remaining portion of vA: va = (5 sin 2000πt + 3 cos 1000 πt) Volts. Page 23 vo = −5cos 2000πt + 25o = − −5sin 2000πt + 25o − 90 o = 5sin 2000πt − 65o ) [ ( Vo = 5∠ − 65 € Page 25 R Av = − 2 R1 o | Vi = 0.001∠0 −5=− o )] ( ( ) 5∠ − 65o Av = = 5000∠ − 65o o 0.001∠0 R2 → R2 = 50 kΩ 10kΩ € 1 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 26 vs = 0.5sin (2000πt ) + sin (4000πt ) + 1.5sin (6000πt ) [ ] The three spectral component frequencies are f1 = 1000 Hz f2 = 2000 Hz f3 = 3000 Hz (a ) The gain of the band - pass filter is zero at both f and f . At f , V = 10(1V ) = 10V , and v = 10.0sin (4000πt ) volts. (b) The gain of the low - pass filter is zero at both f and f . At f , V = 6(0.5V ) = 3V , and v = 3.00sin (2000πt ) volts. 1 3 2 o o 2 3 2 o o Page 27 € 39kΩ(1− 0.1) ≤ R ≤ 39kΩ(1+ 0.1) or 3.6kΩ(1− 0.01) ≤ R ≤ 3.6kΩ(1+ 0.01) € Page 29 VI2 P= R1 + R2 P max = P nom = (1.1x15) 35.1 kΩ ≤ R ≤ 42.9 kΩ or 152 = 4.17 mW 54kΩ 2 0.95x54kΩ 3.56 kΩ ≤ R ≤ 3.64 kΩ = 5.31 mW P min = (0.9x15) 2 1.05x54kΩ = 3.21 mW Page 33 €  10−3  R = 10kΩ 1+ o (−55 − 25) oC = 9.20 kΩ C    10−3  R = 10kΩ 1+ o (85 − 25) oC = 10.6 kΩ C   € 2 ©R. C. Jaeger and T. N. Blalock 08/08/10 CHAPTER 2 Page 47 ni = (2.31x10 30 K cm −3 −6 )   −0.66eV  (300K ) exp 8.62x10−5 eV / K 300K  = 2.27x1013 cm3 ( )  3 ( ) Page 47 € ni = (1.08x10 31 ni = (1.08x10 31 K cm −6 K cm −6 −3 −3 )   −1.12eV  (50K ) exp 8.62x10−5 eV / K 50K  = 4.34x10−39 cm3 ( )  )   −1.12eV  (325K ) exp 8.62x10−5 eV / K 325K  = 4.01x1010 cm3 ( )  3 ( ) 3 ( ) 3  −2 m  cm 3 10 L = 10  → L = 6.13x10 m −39  cm  4.34x10  3 Page 49 € v p = µ p E = 500 E= € cm2  V  3 cm 10  = 5.00x10 V − s  cm  s vn = −µn E = −1350 cm2  V  6 cm 1000  = −1.35x10 V − s cm  s V 1 V V = = 5.00x103 −4 L 2x10 cm cm Page 49 (a) From Fig. 2.5 : The drift velocity for Ge saturates at 6x106 cm / sec. At low fields the slope is constant. Choose E = 100 V/cm v v 4.3x105 cm / s cm2 2.1x105 cm / s cm2 µn = n = = 4300 µp = p = = 2100 E 100V / cm s E 100V / cm s 7 (b) The velocity peaks at 2x10 cm / sec µn = vn 8.5x105 cm / s cm2 = = 8500 E 100V / cm s € 3 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 51   3 −1.12  = 5.40x1024 / cm 6 | ni = 2.32x1012 / cm3 ni2 = 1.08x1031 (400) exp −5 8.62x10 400  ( ) ρ= 1 1 = = 1450 Ω − cm −19 12 σ 1.60x10 2.32x10 (1350) + 2.32x1012 (500) [( ) ( ] )   3 −1.12  = 1.88x10−77 / cm6 | ni = 4.34x10−39 / cm3 ni2 = 1.08x1031 (50) exp −5  8.62x10 (50)  ρ= 1 1 = = 1.69x1053 Ω − cm σ 1.60x10−19 4.34x10−39 (6500) + 4.34x10−39 (2000) [( ) ( ) ] Page 55 €   3 −1.12  = 5.40x1024 / cm 6 ni2 = 1.08x1031 (400) exp −5  8.62x10 (400)  p = N A − N D = 1016 − 2x1015 = 8x1015 holes cm3 n= ni2 5.40x1024 electrons = = 6.75x108 15 p 8x10 cm3 −−− Antimony (Sb) is a Column - V element, so it is a donor impurity. p= ni2 1020 holes = = 5.00x103 16 n 2x10 cm3 n = N D = 2x1016 electrons cm 3 n > p → n - type silicon Page 56 € Reading from the graph for NT = 1016/cm3, 1230 cm2/V-s and 405 cm2/V-s. Reading from the graph for NT = 1017/cm3, 800 cm2/V-s and 230 cm2/V-s. 4 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 58 ( 1 = 0.001 Ω − cm σ ) σ = 1000 = 1.60x10−19 µn n → un n = 6.25x1021 / cm3 = 6.25x1019 (100) | ρ = −−− (a) N D = 2x1016 / cm 3 µn = 92 + | N A = 0 / cm3 1270 0.91  2x10  1+   17 1.3x10  16 | N T = 2x1016 / cm 3 = 1170 cm 2 /V − s | µ p = 48 + | 447 0.76  2x10  1+   16  6.3x10  16 = 363 cm2 /V − s (b) N T = N D + N A = 2x1016 / cm 3 + 3x1016 / cm3 = 5x1016 / cm3 µn = 92 + € 1270 0.91  5x1016  1+   17 1.3x10  = 990 cm 2 /V − s | µ p = 48 + 447 0.76  5x1016  1+   16  6.3x10  = 291 cm2 /V − s Page 59 Boron (B) is a Column - III element, so it is an acceptor impurity. p = N A − N D = 4x1018 holes cm3 | n= ni2 1020 electrons = = 25 18 p 4x10 cm3 | p - type material 4x1018 and mobilities from Fig. 2.8 : µn = 150 cm 2 /V − s | µp = 70 cm2 /V − s 3 cm 1 1 ρ≅ = = 0.022 Ω − cm qµ p p 1.60x10−19 4x1018 (70) NT = ( ) --Indium (In) is a Column - III element, so it is an acceptor impurity. holes p = N A − N D = 7x10 cm3 19 ni2 1020 electrons | n= = = 1.43 | p - type material 19 p 7x10 cm3 7x1019 and mobilities from Fig. 2.8 : µn = 100 cm 2 /V − s | µp = 50 cm2 /V − s 3 cm 1 1 ρ= = = 1.79 mΩ − cm −19 σ 1.60x10 7x1019 (50) NT = ( ) € 5 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 60 −23 1.38x10−23 (300) kT 1.38x10 (50) VT = = = 4.31 mV | VT = = 25.8 mV q 1.602x10−19 1.602x10−19 VT = 1.38x10−23 (400) 1.602x10−19 = 34.5mV −−− Dn =  kT cm2  cm 2 µn = 25.8mV 1362  = 35.1 q V − s s  | Dp =  kT cm2  cm2 µ p = 25.8mV  495  = 12.8 q V − s s  −−− jn = qDn  cm2  1016  10 4 µm  dn A = 1.60x10−19 C 20  3   = 320 2 dx s  cm − µm  cm  cm  j p = −qD p  cm2  1016  10 4 µm  dp A = −1.60x10−19 C 4  3   = −64 2 dx cm  s  cm − µm  cm  € 6 ©R. C. Jaeger and T. N. Blalock 08/08/10 CHAPTER 3 Page 79  2x1018 1020 N N  A D φ j = VT ln 2  = 0.025V ln  1020  ni   ( )  = 1.05 V   ( ) 2(11.7) 8.85x10−14  1 2εs  1 1  1  wdo = + + 1.05) = 2.63x10−6 cm = 0.0263 µm  φ j =  −19 18 20 ( q  N A ND  1.60x10 10   2x10 € Page 80 qN A x p 1 0 Emax = ∫ −qN A dx = εs −x p εs Emax = Emax 1 =− εs ( )( 11.7(8.854x10 F / cm) 1.6x10−19 C 1017 / cm3 1.13x10−5 cm −14 xn ∫ qN D dx = 0 qN D x n εs For the values in Ex.3.2 : ) = 175 kV cm −−− 2(1.05V ) kV cm 2.63x10 cm −1  2x1018  x p = 0.0263µm1+  = 0.0258 µm 1020   Emax = −6 = 798 −1  1020  −4 xn = 0.0263µm1+  = 5.16x10 µm 18  2x10  Page 83 1.381x10 (300) kT 300 n =1 = 0.0259 | T = = 291 K −19 q 1.03 1.602x10 −23 € Page 85 €   0.55     0.70   −15 iD = 40x10−15 Aexp  −1 = 143 µA iD = 40x10 Aexp  −1 = 57.9 mA   0.025    0.025    6x10−3 A  VD = (0.025V ) ln1+  = 0.643 V −15  40x10 A  −−−   −0.04     −2.0   −15 iD = 5x10−15 Aexp  −1 = −3.99 fA | iD = 5x10 Aexp  −1 = −5.00 fA   0.025     0.025   € 7 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 87  40x10−6 A   I  D a V = V ln 1+ = 0.025V ln 1+  = 0.593 V ( ) BE T  I  −15  2x10 A  S  400x10−6 A   I  VBE = VT ln1+ D  = 0.025V ln1+  = 0.651 V ΔVBE = 57.6 mV 2x10−15 A   IS    40x10−6 A   I  (b) VBE = VT ln1+ ID  = 0.0258V ln1+ 2x10−15 A  = 0.612 V   S −6  400x10 A   I  VBE = VT ln1+ D  = 0.0258V ln1+  = 0.671 V ΔVBE = 59.4 mV 2x10−15 A   IS   € Page 89 i  ln D  = ln (iD ) − ln ( I S ) | Assume iD is constant, and EG = EGO  IS   E  dvD k  iD  kT 1 dI S v d 1 dI S = ln  − = − VT | I S = Kni2 = KBT 3 exp − GO  dT q  I S  q I S dT T I S dT  kT   E   E  E  dI S = 3KBT 2 exp− GO  + KBT 3 exp − GO  + GO2  dT  kT   kT  kT  1 dI S 3 EGO 3 qVGO 3 VGO dvD v d 1 dI S v d − VGO − 3VT = + 2= + = + | = − VT = 2 I S dT T kT T kT T VT T dT T I S dT T Page 90 € wd = 0.113µm 1+ 2(V + φ j ) 2(10.979V ) 10V kV = 0.378 µm | Emax = = = 581 −4 0.979V wd cm 0.378x10 cm −−− I S = 10 fA 1+ € 10V = 36.7 fA 0.8V Page 93 11.7 8.854x10−14 F / cm nF nF C jo = = 91.7 2 | C j(0V ) = 91.7 2 10−2 cm 1.25x10−2 cm = 11.5 pF −4 0.113x10 cm cm cm 11.5 pF C j (5V ) = = 4.64 pF 5V 1+ 0.979V −−− ( ) ( )( ) 10−5 A −8 8x10−4 A −8 5x10−2 A −8 CD = 10 s = 4.00 pF | CD = 10 s = 320 pF | CD = 10 s = 0.02 µF 0.025V 0.025V 0.025V 8 € ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 98 5V = 1 mA; I D = 0, VD = 5V 5kΩ The intersection of the two curves occurs at the Q - pt : (0.88 mA, 0.6 V) Two points on the load line : VD = 0, I D = Page 100 € 10 = 10 4 I D + VD  I   I  | VD = VT ln1+ D  | 10 = 10 4 I D + 0.025ln1+ D   IS   IS  Page 101 fzero(@(id) (10-10000*id-0.025*log(1+id/1e-13), 5e-4) € ans = 9.4258e-004 Page 102 fzero(@(id) (10-10000*(1e-14)*(exp(40*vd)-1)-vd), 0.5) ans = 0.6316 Page 109 From the answer, the diodes are on,on,off. 10V - VB VB − 0.6V − (−20V ) VB − 0.6V − (−10V ) = + = 0 → VB = 1.87 V 2.5kΩ 10kΩ 10kΩ 1.87 − 0.6 − (−20V ) 1.87 − 0.6 − (−10V ) I D1 = = 2.13 mA | I D2 = = 1.13 mA | VD3 = −(1.87 − 0.6) = −1.27 V 10kΩ 10kΩ I D1 > 0, I D2 > 0, VD3 < 0. These results are consistent with the assumptions. I1 = I D1 + I D2 € € Page 111 5kΩ 1kΩ Rmin = = 1.67 kΩ | VO = 20V = 3.33 V (VZ is off) | VO = 5 V (VZ is conducting) 20 5kΩ + 1kΩ −1 5 Page 112 VL − 20V VL − 5V V 6.25V − 5V + + L = 0 → VL = 6.25 V | I Z = = 12.5mA 1kΩ 0.1kΩ 5kΩ 0.1kΩ 2 PZ = 5V (12.5mA) + 100Ω(12.5mA) = 78.1 mW −−− Line Regulation = € 0.1kΩ mV = 19.6 0.1kΩ + 5kΩ V Load Regulation = 0.1kΩ 5kΩ = 98.0 Ω 9 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 118 Vdc = VP − Von = 6.3 2 −1 = 7.91 V ΔT = I dc = 7.91V = 15.8 A 0.5Ω  0.527V  1 V 1 2 r = 2  = 0.912 ms ω VP 2π (60)  8.91V  Vr = I dc 15.8 A 1 T= s = 0.527 V C 0.5F 60 θ c = 120π (0.912ms) 180 o = 19.7 o π −−− Vdc = VP − Von = 10 2 −1 = 13.1 V ΔT = I dc = 13.1V = 6.57 A 2Ω  0.1V  1 V 1 2 r = 2  = 0.316 ms ω VP 2π (60) 14.1V  C= I dc 6.57 A 1 T= s = 1.10 F Vr 0.1F 60 θ c = 120π (0.316ms) 180 o = 6.82 o π Page 120 € −23 kT  I D  1.38x10 J / K (300K )  48.6 A  At 300K : VD = ln1+  = ln1+ −15  = 0.994 V q  IS  1.60x10−19 C  10 A  −23 kT  I D  1.38x10 J / K (273K + 50K )  48.6 A  At 50 C : VD = ln1+  = ln1+ −15  = 1.07 V q  IS  1.60x10−19 C  10 A   48.6 A  kT  I D  Note : For VT = 0.025V , VD = ln1+  = 0.025V ln1+ −15  = 0.961 V q  IS   10 A  o Page 127 € Vrms = Vdc + Von 2 = 15 + 1 2 = 11.3 V | C = I dc 2A 1 T= s = 0.222F = 222,000 µF Vr 60 0.01(15V ) I SC = ωCVP = 2π (60Hz )(0.222F )(16V ) = 1340 A ΔT = (0.01)(15) = 0.363 ms | I = I 2T = 2 A 2s 1 V 1 2 r = 2 = 184 A P dc ω VP 2π (60) 16 ΔT 60(0.363ms) € 10 ©R. C. Jaeger and T. N. Blalock 08/08/10 CHAPTER 4 Page 153 ( ) 14 εox cm2 3.9 8.854x10 F / cm C µA K = µn = 500 = 69.1x10−6 2 = 69.1 2 −7 Tox V −s 25x10 cm V −s V --W µA  20µm  µA µA  60µm  µA Kn = Kn' = 50 2   = 1000 2 Kn = 50 2   = 1000 2 L V  1µm  V V  3µm  V µA  10µm  µA Kn = 50 2   = 2000 2 V  0.25µm  V --For VGS = 0V and 1V , VGS < VTN and the transistor is off. Therefore I D = 0. ' n VGS - VTN = 2 -1.5 = 0.5V and VDS = 0.1 V → Triode region operation W V  µA  10µm  0.1 2 I D = Kn' VGS − VTN − DS VDS = 25 2   2 −1.5 − 0.1V = 11.3 µA L 2  2 V  1µm  VGS - VTN = 3 -1.5 = 1.5V and VDS = 0.1 V → Triode region operation W V  µA  10µm  0.1 2 I D = Kn' VGS − VTN − DS VDS = 25 2   3 −1.5 − 0.1V = 36.3 µA L 2  2 V  1µm  Kn' = 25 µA  100µm  µA  = 250 2 2  V  1µm  V Page 154 € 1 1 = 4.00 kΩ | Ron = = 1.00 kΩ µA µA ' W Kn (VGS − VTN ) 250 2 (2 −1) 250 2 (4 −1) L V V 1 1 VGS = VTN + = 1V + = 3.00 V µA Kn Ron 250 2 (2000Ω) V Ron = 1 = € 11 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 157 VGS - VTN = 5 -1 = 4 V and VDS = 10 V → Saturation region operation 2 2 Kn 1 mA VGS − VTN ) = 5 −1) V 2 = 8.00 mA ( 2 ( 2 2V W W 1mA 25 Kn = Kn' → = = W = 25L = 8.75 µm L L 40µA 1 ID = −−− Assuming saturation region operation, 2 2 Kn 1 mA VGS − VTN ) = 2.5 −1) V 2 = 1.13 mA ( 2 ( 2 2V mA g m = Kn (VGS − VTN ) = 1 2 (2.5 −1)V = 1.50 mS V 2I D 2(1.125mA) Checking : g m = = 1.50 mS VGS − VTN (2.5 −1)V ID = € Page 158 VGS - VTN = 5 -1 = 4 V and VDS = 10 V → Saturation region operation 2 2 Kn 1 mA VGS − VTN ) (1+ λVDS ) = 5 −1) V 2 1+ 0.02(10) = 9.60 mA ( 2 ( 2 2V 2 2 K 1 mA I D = n (VGS − VTN ) (1+ λVDS ) = 5 −1) V 2 1+ 0(10) = 8.00 mA 2 ( 2 2V --VGS - VTN = 4 -1 = 3 V and VDS = 5 V → Saturation region operation [ ID = [ ] ] 2 2 2 Kn 25 µA VGS − VTN ) (1+ λVDS ) = 4 −1 V 1+ 0.01(5) = 118 µA ( ( ) 2 2 V2 2 2 K 25 µA I D = n (VGS − VTN ) (1+ λVDS ) = 5 −1) V 2 1+ 0.01(10) = 220 µA 2 ( 2 2 V [ ID = [ ] ] Page 159 € Assuming pinchoff region operation, I D = VGS = VTN + 2 2 Kn 50 µA 0 − VTN ) = +2V ) = 100 µA ( 2 ( 2 2 V 2(100 µA) 2I D = 2V + = 4.00 V Kn 50µA /V 2 −−− Assuming pinchoff region operation, I D = € 2 2 Kn 50 µA VGS − VTN ) = 1− −2V = 225 µA ( ( ) 2 2 V2 [ 12 ] ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 161 ( V + 0.6V − 0.6V ) = 1+ 0.75( = 1+ 0.75( 1.5 + 0.6 − 0.6 ) = 1.51 V | V VTN = VTO + γ VTN ) 0 + 0.6 − 0.6 = 1 V SB TN ( ) = 1+ 0.75 3 + 0.6 − 0.6 = 1.84 V --- (a ) V is less than the threshold voltage, so the transistor is cut off and ID = 0. ( b) V - VTN = 2 -1 = 1 V and VDS = 0.5 V → Triode region operation GS GS  V  mA  0.5  2 I D = KnVGS − VTN − DS VDS = 1 2  2 −1− 0.5V = 375 µA 2  2  V   (c) VGS - VTN = 2 -1 = 1 V and VDS = 2 V → Saturation region operation 2 2 Kn mA VGS − VTN ) (1+ λVDS ) = 0.5 2 (2 −1) V 2 1+ 0.02(2) = 520 µA ( 2 V [ ID = € ] Page 163 (a ) VGS is greater than the threshold voltage, so the transistor is cut off and I D = 0. ( b) V GS - VTN = -2 + 1 = 1 V and VDS = 0.5 V → Triode region operation  V  mA  −0.5  2 I D = KnVGS − VTN − DS VDS = 0.4 2  −2 + 1− (−0.5)V = 150 µA 2 2 V     (c) V GS ID = - VTN = −2 + 1 = 1 V and VDS = 2 V → Saturation region operation 2 2 Kn 0.4 mA VGS − VTN ) (1+ λVDS ) = −2 + 1) V 2 1+ 0.02(2) = 208 µA ( 2 ( 2 2 V [ ] € 13 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 167  µF  CGC = 200 2  5x10−6 m 0.5x10−6 m = 0.500 fF m   ( )( )  CGC pF  −6 + CGSOW = 0.25 fF +  300  5x10 m = 1.75 fF 2 m    2 pF  −6 Saturation region : CGS = CGC + CGSOW = 0.333 fF +  300  5x10 m = 1.83 fF 3 m    pF  −6 CGD = CGSOW =  300  5x10 m = 1.50 fF m  Triode region : CGD = CGS = ( € ( ) ( ) ) Page 169 KP = Kn = 150U | LAMBDA = λ = 0.0133 | VTO = VTN = 1 | PHI = 2φ F = 0.6 W = W = 1.5U | L = L = 0.25U Page 170 €  1µm 2 Circuits/cm ∝ α =   = 16  0.25µm  2 2 Power - Delay Product ∝ € 1 1 1 = 3= → 64 times improvement 3 64 α 4 Page 171 ε W /α  v DS  * * iD* = µn ox  vGS − VTN − v DS = α iD | P = VDD iD = VDD (α iD ) = α P Tox / α L / α  2  P* αP P = = α3 * A A (W / α )( L / α ) −−− (a ) fT = 1 500cm2 /V − s (1V ) = 7.96 GHz | 2 −4 2π 10 cm ( ) (b) fT = 1 500cm2 /V − s (1V ) = 127 GHz 2π 0.25x10−4 cm 2 ( ) −−−   5 V  −5 V V V  −4 ≥ 105 → L = 105  10 cm = 10 V | L = 10  10 cm = 1 V L cm  cm   cm  ( ) ( ) € 14 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 172 (a ) From the graph for VGS = 0.25 V , I D ≅ 10−18 A | (b) From the graph for V = V − 0.5 V , I ≅ 3x10 (c) I = (10 transistors)(3x10 A/transistors) = 3 µA GS 9 TN D −15 A -15 Page 176 2 € Active area = 10Λ(12Λ) = 120Λ2 = 120(0.125µm ) = 1.88 µm 2 L = 2Λ = 0.250 µm | W = 10Λ = 1.25 µm 2 Gate area = 2Λ(10Λ) = 20Λ2 = 20(0.125µm) = 0.313 µm 2 2 Transistor area = (10Λ + 2Λ + 2Λ)(12Λ + 2Λ + 2Λ) = 224Λ2 = 224(0.125µm ) = 3.50 µm 2 (10 µm) N= 4 3.50µm € 2 2 = 28.6 x 106 transistors Page 180 Assume saturation region operation and λ = 0. Then I D is indpendent of VDS , and I D = 50 µA. VDS = VDD − I D RD = 10 − 50kΩ(50µA) = 7.50 V. VDS ≥ VGS − VTN , so our assumption was correct. Q - Point = (50.0 µA, 7.50 V ) --270kΩ 10V = 2.647 V | REQ = 270kΩ 750kΩ | Assume saturation region. 270kΩ + 750kΩ 2 2 25x10−6 A ID = 2.647 −1 V = 33.9 µA | VDS = VDD − I D RD = 10 −100kΩ(33.9µA) = 6.61 V. ( ) 2 V2 VDS ≥ VGS − VTN , so our assumption was correct. Q - Point = (33.9 µA, 6.61 V ) VEQ = --2 30x10−6 A 3 −1) V 2 = 60.0 µA 2 ( 2 V = VDD − I D RD = 10 −100kΩ(60.0µA) = 4.00 V. VDS ≥ VGS − VTN , so our assumption was correct. VGS does not change : VGS = 3.00 V | I D = VDS Q - Point = (60.0 µA, 4.00 V ) € 15 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 181 2 25x10−6 A 3 −1.5) V 2 = 28.1 µA 2 ( 2 V = VDD − I D RD = 10 −100kΩ(28.1µA) = 7.19 V. VDS ≥ VGS − VTN , so our assumption was correct. VGS does not change : VGS = 3.00 V | I D = VDS Q - Point = (28.1 µA, 7.19 V ) --VDS = 10 − VDS = ( ) (3 −1) (1+ 0.01V ) → V 2 25x10−6 105 10 − 5 V = 4.76 V 1.05 2 DS ID = DS = 10 − 5(1+ 0.01VDS ) 2 25x10−6 3 −1) 1+ 0.01(4.76) = 52.4 µA ( 2 [ ] Page 182 € 10V = 150µA. 66.7kΩ = 3 - V curve at I D = 50 µA, VDS = 6.7 V. For I D = 0, VDS = 10 V. For VDS = 0, I D = The load line intersects the VGS € 16 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 185 Upper group  2  2V V + VGS  − 2VTN  + VTN2 − EQ = 0 Kn RS  Kn RS  2 GS 2  1   1  2V | VGS = − − VTN  ±  − VTN  − VTN2 + EQ Kn RS  Kn RS   Kn RS  2  1  2VTN 2V 1 1 VGS = VTN − ±  + VTN2 − VTN2 + EQ = VTN +  − Kn RS Kn RS Kn RS  Kn RS  Kn RS ( 1+ 2K R (V n S EQ ) − VTN ) −1 −−− Assume saturation region operation. ID = 1 2Kn RS2 ( ) 2 1+ 2Kn RS (VEQ − VTN ) −1 = 1 2(30µA)(39kΩ) 2 ( ) 2 1+ 2(30µA)(39kΩ)(4 −1) −1 = 36.8 µA VDS = 10 −114kΩ(36.8µA) = 5.81 V | Saturation region is correct. | Q - Point : (36.8 µA, 5.81 V ) −−− Assume saturation region operation. I D = 1 2(25µA)(39kΩ) 2 ( ) 2 1+ 2(25µA)(39kΩ)(4 −1.5) −1 = 26.7 µA VDS = 10 −114kΩ(26.7µA) = 6.96 V | Saturation region is correct. | Q - Point : (26.7 µA, 6.96 V ) Assume saturation region operation. I D = 1 2(25µA)(62kΩ) 2 ( ) 2 1+ 2(25µA)(62kΩ)(4 −1) −1 = 36.8 µA VDS = 10 −137kΩ(25.4µA) = 6.52 V | Saturation region is correct. | Q - Point : (25.4 µA, 6.52 V ) € 17 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 185 Lower group R1 1MΩ VEQ = VDD = 10V = 4 V | Assume saturation region operation. R1 + R2 1MΩ + 1.5MΩ ID = 1 2Kn RS2 ( ) 2 1+ 2Kn RS (VEQ − VTN ) −1 = 1 2(25µA)(1.8kΩ) 2 ( ) 2 1+ 2(25µA)(1.8kΩ)(4 −1) −1 = 99.5 µA VDS = 10 − 40.8kΩ(99.5µA) = 5.94 V | Saturation region is correct. | Q - Point : (99.5 µA, 5.94 V ) VEQ = ID = R1 1.5MΩ VDD = 10V = 6 V | Assume saturation region operation. R1 + R2 1.5MΩ + 1MΩ 1 2(25µA)(22kΩ) 2 ( ) 2 1+ 2(25µA)(22kΩ)(6 −1) −1 = 99.2 µA VDS = 10 − 40kΩ(99.2µA) = 6.03 V | Saturation region is correct. | Q - Point : (99.2 µA, 6.03 V ) −−− I Bias = VDD V 10V → R1 + R2 = DD = = 5 MΩ R1 + R2 I Bias 2µA VEQ = V R1 4V VDD → R1 = ( R1 + R2 ) EQ = 5MΩ = 2 MΩ R1 + R2 VDD 10V R2 = 5MΩ − R1 = 3 MΩ | REQ = R1 R2 = 1.2 MΩ Page 187 € ( VGS = 6 − 22000I D VSB = 22000I D VTN = 1+ 0.75 VSB + 0.6 − 0.6 ) ID = 2 25µA VGS − VTN ) ( 2 Spreadsheet iteration yields ID = 83.2 µA. Page 183 € [ ( ) ] Equation 4.55 becomes 6 - 1 + 0.75 VSB + 0.6 − 0.6 + 2.83 − VSB = 0. VSB2 − 6.065VSB + 7.231 = 0 → VSB = 1.63V. RS = 1.63V = 16.3 kΩ →16 kΩ 10−4 A RD = (10 − 6 −1.63)V = 23.7kΩ → 24 kΩ 10−4 A € 18 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 189 Assume saturation region operation. 10 − 6 = ( 25x10−6 62x10 4 2 ) (V GS 2 + 1) − VGS → VGS2 + 0.710VGS − 4.161 = 0 → VGS = −2.426V , + 1.716V 2 25x10 −2.426 + 1) = 25.4 µA | VDS = − 10 −137kΩ(25.4µA) = −6.52 V ( 2 Saturation region is correct. | Q - Point : (25.4 µA, - 6.52 V ) −6 ID = € [ ] Page 195 (a) VDS = 3 V , VGS − VP = −2 − (−3.5) = +1.5 V. The transistor is pinched off. 2   −2V   V 2 I D = I DSS 1− GS  = 1mA 1−   = 184 µA | Pinchoff requires VDS ≥ VGS − VP = +1.5 V  VP    −3.5V  (b) VDS = 6 V , VGS − VP = −1− (−3.5) = +2.5 V. The transistor is pinched off. 2 2   −1V   VGS  I D = I DSS 1−  = 1mA 1−   = 510 µA | Pinchoff requires VDS ≥ VGS − VP = +2.5 V  VP    −3.5V  (c) VDS = 0.5 V , VGS − VP = −2 − (−3.5) = +1.5 V. The transistor is in the triode region. ID = 2(1mA)  2I DSS  VDS  0.5 V − V − V = −2 + 3.5 −    0.5 = 51.0 µA GS P DS 2 2  2 VP2    −3.5 ( ) Pinchoff requires VDS ≥ VGS − VP = +1.5 V −−− (a ) VDS = 0.5 V , VGS − VP = −2 − (−4) = +2 V. The transistor is in the triode region. ID = (b) 2(0.2mA)  2I DSS  VDS  0.5 V − V − V = −2 + 4 −    0.5 = 21.9 µA GS P DS 2 2  2  VP2  (−4)  VDS = 6 V , VGS − VP = −1− (−4) = +3 V. The transistor is pinched off. 2   −1V   V 2 I D = I DSS 1− GS  = 0.2mA 1−   = 113 µA  VP    −4V  € 19 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 197 (a) VDS = −3 V , VGS − VP = 3 − 4 = −1 V. The transistor is pinched off.  VGS 2  3V 2 I D = I DSS 1−  = 2.5mA 1−  = 156 µA | Pinchoff requires VDS ≤ VGS − VP = −1 V  4V   VP  ( b) VDS = −6 V , VGS − VP = 1− (4) = −3 V. The transistor is pinched off.  VGS 2  1V 2 I D = I DSS 1−  = 2.5mA 1−  = 1.41 mA | Pinchoff requires VDS ≤ VGS − VP = −3 V  4V   VP  (c) VDS = −0.5 V , VGS − VP = 2 − (4) = −2 V. The transistor is in the triode region. ID = 2(2.5mA)  2I DSS  VDS  −0.5  V − V − V = 2 − 4 −    (−0.5) = 273 µA GS P DS 2  2  VP2  42  Pinchoff requires VDS ≤ VGS − VP = −2 V Page 198 € BETA = I DSS 2.5mA = = 0.625 mA | VTO = VP = −2 V | LAMBDA = λ = 0.025 V -1 2 2 VP (−2) −−− BETA = I DSS 5mA = 2 = 1.25 mA | VTO = VP = 2 V | LAMBDA = λ = 0.02 V -1 2 VP 2 € 20 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 200 VTO = VP = −5 V | BETA = I DSS 5mA = = 0.2 mA | LAMBDA = λ = 0.02 V -1 VP2 (−5)2 −−− VGS = VG − VS = −IG RG − I S RS = 0 − I D RS = −I D RS 2 2 V   V  2 K K K VGS = − n (VGS − VTN ) RS = − n VTN2 RS  GS −1 = −I DSS RS 1− GS  for I DSS = n VTN2 and VP = VTN 2 2 2  VTN   VP  2 2  V   V  2 0.4mA VGS = − −5) (1kΩ)1− GS  = 51+ GS  → VGS2 −15VGS + 25 = 0 and the rest is identical. ( 2 5   −5   --Assuming pinchoff, I D = 1.91 mA and VDS = 9 −1.91mA(2kΩ + 1kΩ) = 3.27 V. VGS − VP = 3.09 V , VDS > VGS − VP , and pinchoff is correct. --2  V   VGS 2 −3 3 2 GS Assuming pinchoff, VGS = −I DSS RS 1−  = − 5x10 2x10 1+  → VGS + 12.5VGS + 25 = 0 5    VP  ( )( ) 2 2  V   −2.5  GS VGS = −2.5 V | I D = I DSS 1−  = 5mA1−  = 1.25 mA −5    VP  VDS = 12 −1.25mA(2kΩ + 2kΩ) = 7.00 V. VGS − VP = −2.5 − (−5) = +2.5 V , VDS > VGS − VP , and pinchoff is correct. Q - Point : (1.25 mA, 7.00 V ) --- (a ) V G = −IG RG = −10nA(680kΩ) = −6.80 mV. 2 2  VGS   VGS  −3 3 2 VGS = VG − VS = −IG RG − I DSS RS 1−  = −.00680 − 5x10 10 1+  → VGS −15VGS + 25 = 0 V 5    P  ( )( ) The value of VG is insignificant with respect to the constant term of 25. So the answers are the same to 3 significant digits. (b) V G = −IG RG = −1µA(680kΩ) = 0.680 V and now cannot be neglected. 2  V 2  VGS  −3 3 2 GS VGS = VG − VS = −IG RG − I DSS RS 1−  = −0.680 − 5x10 10 1+  → VGS −15VGS + 28.4 = 0 V 5    P  ( )( ) 2  V   −2.226 2 GS VGS = −2.226 V | I D = I DSS 1−  = 5mA1−  = 1.54 mA −5    VP  VDS = 12 −1.54mA(2kΩ + 1kΩ) = 7.38 V | Q - Point : (1.54 mA, 7.38 V ) € 21 ©R. C. Jaeger and T. N. Blalock 08/09/10 CHAPTER 5 Page 223 (a ) βF = αF 0.970 0.993 0.250 = = 32.3 | β F = = 142 | β F = = 0.333 1− α F 1− 0.970 1− 0.993 1− .250 (b) αF = βF 40 200 3 = = 0.976 | α F = = 0.995 | α F = = 0.750 β F + 1 41 201 4 Page 225 €   0.700   −9.30  10−15 A   −9.30   iC = 10−15 Aexp − exp exp    −  −1 = 1.45 mA 0.5   0.025    0.025    0.025    0.700   −9.30  10−15 A   0.700   iE = 10−15 Aexp − exp exp    +  −1 = 1.46 mA  0.025  100   0.025     0.025  10−15 A   0.700   10−15 A   −9.30   iB = exp exp  −1 +  −1 = 14.5 µA 100   0.025   0.5   0.025   Page 227 €   0.750   0.700  10−16 A   0.700   iC = 10−16 Aexp exp  − exp  −  −1 = 563 µA 0.4   0.025    0.025    0.025    0.750   0.700  10−16 A   0.750   iE = 10−16 Aexp − exp exp    +  −1 = 938 µA 75   0.025    0.025    0.025  iB = 10−16 A   0.750   10−16 A   0.700   exp exp  −1 +  −1 = 376 µA 75   0.025   0.4   0.025   −−−   0.750   −2  iT = 10−15 Aexp  − exp  = 10.7 mA  0.025   0.025    0.750   −4.25  iT = 10−16 Aexp  − exp  = 1.07 mA  0.025    0.025  € 22 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 230  10−4 A  I  VBE = VT ln C + 1 = 0.025V ln −16 + 1 = 0.691 V  IS   10 A   10−3 A  I  VBE = VT ln C + 1 = 0.025V ln −16 + 1 = 0.748 V  IS   10 A  Page 231 € € npn :VBE > 0, VBC < 0 → Forward − Active Region | pnp :VEB > 0, VCB > 0 → Saturation Region Page 233 αF 0.95 βF = = = 19 1− α F 0.05 VBE = 0, VBC I E = I S = 0.100 fA IB = − IS 10−16 A =− = −0.300 fA βR 0.333 VBE << 0, VBC << 0 : IC = IS = 3x10−16 A = 0.300 fA βR IE = € αR 0.25 1 = = 1− α R 0.75 3   1 1  << 0 : IC = I S 1+  = 10−16 A1+  = 0.400 fA  0.333   βR  βR = I S 10−16 A = = 5.26 aA βF 19.0 IB = − IS IS 10−16 A 10−16 A − =− − = −0.305 fA βF βR 19.0 1/ 3 Page 235 (a ) The currents do not depend upon VCC as long as the collector - base junction is reverse biased by more than 0.1 V. (Later when Early votlage VA is discussed, one should revisit this problem.) IE 100µA = = 1.96 µA | IC = β F I B = 50I B = 98.0 µA βF + 1 51 I   98.0µA  = VT ln C + 1 = 0.025V ln −16 + 1 = 0.690 V  10 A   IS  (b) I VBE E = 100 µA | I B = € 23 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 236 (a ) The currents do not depend upon VCC as long as the collector - base junction is reverse biased by more than 0.1 V. (Later when Early voltage VA is discussed, one should revisit this problem.) (b) Forward - active region : I B = 100 µA | I E = (β F + 1) I B = 5.10 mA | IC = β F I B = 5.00 mA I   5.00mA  VBE = VT ln C + 1 = 0.025V ln −16 + 1 = 0.789 V | Checking : VBC = −5 + 0.789 = −4.21  10 A   IS  −−− Forward - active region with VCB ≥ 0 requires VCC ≥ VBE or VCC ≥ 0.764 V € Page 238 (a) Resistor R is changed. −0.7V − (−9V ) IE = 5.6kΩ = 1.48 mA | I B = IE I = E = 29.1 µA | IC = β F I B = 50I B = 1.45 mA β F + 1 51 VCE = VC − VE = (9 − 4300IC ) − (−0.7) = 3.47 V | Q - Po int : (1.45 mA, 3.47 V ) (b) I E = −0.7V − (−9V ) 8.3V βF + 1 51 IC = 100µA = 102µA | R = = = 81.4 kΩ βF 50 102µA 102µA The nearest 5% value is 82 kΩ. € Page 239 −0.7V − (−9V ) I I IE = = 1.48 mA | I B = E = E = 29.1 µA | IC = β F I B = 50I B = 1.45 mA 5.6kΩ β F + 1 50 −−− I  βF + 1 51 IC = IC = 1.02IC VBE = VT ln C + 1 = 0.025ln 2x1015 IC + 1 βF 50  IS    V   VBE + 8200 1.02 5x10−16 exp BE  −1 = 9 → VBE = 0.7079 V using a calculator solver  0.025    0.7079  or spreadsheet. IC = 5x10−16 exp  = 992 µA | VCE = 9 − 4300IC − (−0.708) = 5.44 V  0.025  −−− ( IE = ( I SD = ) ) I SBJT 2x10−14 A = = 21.0 fA αF 0.95 € 24 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 242 Resistor R is changed : −IC = −0.7V − (−9V ) 5.6kΩ = 1.48 mA | I B = −IC −I = C = 0.741 mA | − I E = β R I B = (1) I B = 0.741 mA βR + 1 2 Page 244 € VCESAT  1mA  1+    1  2(40µA)   = (0.025V ) ln   = 99.7 mV  0.5  1mA  1−   50(40µA)   −−− VBESAT VBCSAT     0.1mA + (1− 0.5)1mA  = (0.025V ) ln = 0.694 mV   −15  1  10 A + 1− 0.5   50     1mA   0.1mA − 50   = 0.627 mV | V = (0.025V ) ln CESAT = VBESAT − VBCSAT = 67.7mV   −15  1  1 10 A  + 1− 0.5  0.5 50   Page 247 € (a ) Dn = kT µn = 0.025V 500cm2 /V − s = 12.5cm2 / s q ( ) ( )( ( )( )( ) −19 2 −4 2 20 6 qADn ni2 1.6x10 C 50µm 10 cm / µm 12.5cm / s 10 / cm = 10−18 A = 1 aA ( b) I S = N W = 18 3 10 / cm (1µm) AB € ) Page 250 1.38x10−23 J / K (373K ) I 10 A VT = = 32.2mV | CD = C τ F = 4x10−9 s = 1.24 µF −19 VT 0.0322V 1.60x10 C −−− f 300 MHz fβ = T = = 2.40 MHz βF 125 ( ) ( ) € 25 ©R. C. Jaeger and T. N. Blalock 08/09/10 Page 251  0.7  10   10  1.74mA IC = 10−15 Aexp = 19.3 µA 1+  = 1.74 mA | β F = 751+  = 90.0 | I B = 90.0  0.025  50   50   0.7  1.45mA IC = 10−15 Aexp = 19.3 µA  = 1.45 mA | β F = 75 | I B = 75  0.025  € € Page 253 40 −4 40 −3 gm = 10 A = 4.00 mS | g m = 10 A = 40.0 mS V V CD = 4.00mS (25 ps) = 0.100 pF | CD = 40.0mS (25 ps) = 1.00 pF ( ) ( Page 256 −23 kT 1.38x10 (300) VT = = = 25.9 mV | IS = q 1.60x10−19 ) IC 350µA = = 1.39 fA  VBE   0.68  exp  exp   0.0259   VT  BF = 80 | VAF = 70 V Page 260 € 18kΩ 12V = 4.00 V | REQ = 18kΩ 36kΩ = 12 kΩ 18kΩ + 36kΩ 4.00 − 0.7 V IB = = 2.687 µA | IC = 75I B = 202 µA | I E = 76I B = 204 µA 12 + (75 + 1)16 kΩ VEQ = VCE = 12 − 22000IC −16000I E = 4.29 V | Q - po int : (202 µA, 4.29 V ) −−− 180kΩ 12V = 4.00 V | REQ = 180kΩ 360kΩ = 120 kΩ 180kΩ + 360kΩ 4.00 − 0.7 V IB = = 2.470 µA | IC = 75I B = 185 µA | I E = 76I B = 188 µA 120 + (75 + 1)16 kΩ VEQ = VCE = 12 − 22000IC −16000I E = 4.29 V | Q - po int : (185 µA, 4.93 V ) € 26 ©R. C. Jaeger and T. N. Blalock 08/08/10 Page 261 I 50I B I2 = C = = 10I B 5 5 −−− 18kΩ 12V = 4.00 V | REQ = 18kΩ 36kΩ = 12 kΩ 18kΩ + 36kΩ 4.00 − 0.7 V IB = = 0.4111 µA | IC = 500I B = 205.6 µA | I E = 76I B = 206.0 µA 12 + (500 + 1)16 kΩ VEQ = VCE = 12 − 22000IC −16000I E = 4.18 V | Q - point : (206 µA, 4.18 V ) € Page 262 The voltages all remain the same, and the currents are reduced by a factor of 10. Hence all the resistors are just scaled up by a factor of 10. 120 kΩ →1.2 MΩ 82 kΩ → 820 kΩ 6.8 kΩ → 68 kΩ Page 264 €   76 VCE = 0.7 V at the edge of saturation. 12V -  RC + 16kΩ(205µA) ≥ 0.7V → RC ≤ 38.9 kΩ 75   −−− VBESAT = 4 −12kΩ(24µA) −16kΩ(184µA) = 0.768 V VCESAT = 12 − 56kΩ(160µA) −16kΩ(184µA) = 0.096 V € Page 265 9 − 0.7 V IB = = 95.4 µA | IC = 50I B = 4.77 mA | I E = 51I B = 4.87 mA 36 + (50 + 1)1 kΩ VCE = 9 −1000( IC + I B ) = 4.13 V | Q - point : (4.77 mA, 4.13 V ) € Page 266 VBE (V) 0.70000 0.67156 0.67178 0.67178 IC (A) V'BE (V) 2.0155E-04 2.0328E-04 2.0327E-04 2.0327E-04 0.67156 0.67178 0.67178 0.67178 27 ©R. C. Jaeger and T. N. Blalock 08/09/10 Microelectronic Circuit Design Fourth Edition - Part II Solutions to Exercises CHAPTER 6 Page 292 NM L = 0.8V − 0.4V = 0.4 V | NM H = 3.6V − 2.0V = 1.6 V € Page 294 V10% = VL + 0.1 (ΔV ) = −2.6V + 0.1 −0.6 − (−2.6) = −2.4 V [ ] [ ] Checking : V10% = VH − 0.9 (ΔV ) = −0.6V − 0.9 −0.6 − (−2.6) = −2.4 V [ ] V90% = VH − 0.1 (ΔV ) = −0.6V − 0.1 −0.6 − (−2.6) = −0.8 V [ ] Checking : V90% = VL + 0.9 (ΔV ) = −2.6V + 0.9 −0.6 − (−2.6) = −0.8 V V50% = € VH + VL −0.6 − 2.6 = = −1.6 V | t r = t 4 − t3 = 3 ns | t f = t2 − t1 = 5 ns 2 2 Page 295 At P = 1 mW : PDP = 1mW (1ns) = 1 pJ At P = 3 mW : PDP = 3mW (1ns) = 3 pJ At P = 20 mW : PDP = 20mW (2ns) = 40 pJ € Page 297 Z = ( A + B)( B + C) = AB + AC + BB + BC = AB + BB + AC + BB + BC Z = AB + B + AC + B + BC = B( A + 1) + AC + B(C + 1) = B + AC + B Z = B + B + AC = B + AC € 1 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 300 P 0.4mW V − VL 2.5V − 0.2V I DD = = = 160 µA | R = DD = = 14.4 kΩ VDD 2.5V I DD 160µA W  A W   0.2  4.44 2 1.6x10−4 A = 10−4 2   2.5 − 0.6 − 0.2 V →   = 2  1 V  L S   L S € Page 301 V − VL 3.3V − 0.1V I DD = DD = = 31.4µA R 102kΩ W  A W   0.1 2.09 31.4x10−6 A = 6x10−5 2    3.3 − 0.75 − 0.1 V 2 →   = 2  1 V  L S   L S Page 303 € Ron 2.5V → Ron = 1.84 kΩ Ron + 28.8kΩ W  W  1 2.98 →  =   =   1 0.15  L S  L S 10−4  2.5 − 0.60 − (1.84kΩ) 2   0.15V = −−− Ron = 1  1.03  0.2  6x10−5   3.3 − 0.75 −  2   1  = 6.61 kΩ | VL = 6.61kΩ 3.3V = 0.201 V 6.61kΩ + 102kΩ −−−  1  V2 1 V2 = =V  =  Kn R  A Ω V Page 305 € 1.03  6.30 5 Kn R = 6x10−5   1.02x10 = V  1  ( ) NM H = 3.3 − 0.75 + ( ) 1 3.3 −1.63 = 1.45 V 6.30 2(6.30) NM L = 0.75 + 2(3.3) 1 − = 0.318 V 6.30 3(6.30) € 2 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 309 Using MATLAB : fzero(@(vh) ((vh -1.9 - 0.5* sqrt(0.6))^2 - 0.25(vh + 0.6)), 1) | ans = 1.5535 fzero(@(vh) ((vh -1.9 - 0.5* sqrt(0.6))^2 - 0.25(vh + 0.6)), 4) | ans = 3.2710 −−− [ )] ( VH = 5 − 0.75 + 0.5 VH + 0.6 − 0.6 → VH = 3.61 V fzero(@(vh) (5- 0.75 - 0.5* (sqrt(vh + 0.6) - sqrt(0.6)) - vh), 1) | ans = 3.6112 −−− (a ) 80x10−6 A = 100x10−6 W  A W   0.15  6.10 2  1.55 − 0.60 − 0.15 V →   = 2 2  1 V  L S   L S ( ) VTNL = 0.6 + 0.5 .15 + 0.6 − 0.6 = 0.646 V  W  0.551 2 2 100x10−6 A W  1 =  (2.5 − 0.15 − 0.646) V →   = 2 2 1 1.82 V  L L  L L W  A W   0.1 8.89 (b) 80x10−6 A = 100x10−6 2   1.55 − 0.60 − 0.1 V 2 →   = 2  1 V  L S   L S 80x10−6 A = ( ) VTNL = 0.6 + 0.5 .1+ 0.6 − 0.6 = 0.631 V  W  0.511 2 2 100x10 A W  1 2.5 − 0.1− 0.631 V → =     = ( ) 2 2 1 1.96 V  L L  L L −6 80x10−6 A = € Page 312 The high logic level is unchanged : VH = 2.11 W  A W   0.1 9.16 60x10−6 A = 50x10−6 2    2.11− 0.75 − 0.1 V 2 →   = 2  1 V  L S   L S ( ) VTNL = 0.75 + 0.5 .1+ 0.6 − 0.6 = 0.781 V 60x10−6 A =  W  0.410 2 2 50x10−6 A  W  1 =  (3.3 − 0.1− 0.781) V →   = 2 2 1 2.44 V  L L  L L € 3 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 314 Using MATLAB : fzero(@(vh) ((vh -1.9 - 0.5* sqrt(0.6))^2 - 0.25(vh + 0.6)), 1) | ans = 1.5535 −−− γ = 0 → VTN = 0.6V | VH = 2.5 - 0.6 = 1.9 V | I DD = 0 for vO = VH   2 VL  100x10−6  2  −6 10 100x10  1.9 − 0.6 − VL =  (2.5 − VL − 0.6) 2 2  1   1 10  0.235 6VL2 −116.8VL + 3.61 = 0 → VL = 0.235V | I DD = 100x10−6  1.9 − 0.6 − 0.235 = 278 µA 2   1  2 100x10−6  2  Checking : I DD =  (2.5 − 0.235 − 0.6) = 277 µA 2  1 € Page 319 VTNL = −1.5 + 0.5 0.2 + 0.6 − 0.6 = −1.44V ( ) W    W  1.17 0.2  60.6x10−6 = 100x10−6    3.3 − 0.6 − 0.2 →   = 2  1  L S   L S  W  0.585 2 100x10−6  W  1 60.6x10−6 = =   (0 −1.44) →   = 2 1 1.71  L L  L L Page 320 €  2.22  0.2  I DS = 100x10−6   2.5 − 0.6 − 0.2 = 79.9 µA which checks. 2   1  € Page 321 The PMOS transistor is still saturated so I DL = 144 µA, and VH = 2.5 V.  5 V  144x10−6 = 100x10−6   2.5 − 0.6 − L VL → VL = 0.158 V 2  1  Page 326 € W 2.22 = in parallel with transistors A and B. L 1  W  1.81 The W/L ratio of the load transistor remains unchanged :   = 1  L L Place a third transistor with € 4 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 327 Place a third transistor in series with transistors A and B. W  2.22 6.66 The new W/L ratios of transistors A, B and C are   =3 = . 1 1  L  ABC  W  1.81 The W/L ratio of the load transistor remains unchanged :   = 1  L L Page 333 € M L1 is saturated for all three voltages. I DD = 2 40x10−6 1.11   −2.5 − (−0.6) = 80.1 µA 2  1 L [ ] −−− The voltages can be estimated using the on - resistance method. For the 11000 case, RonA = 132mV − 64.4mV 64.4mV = 844 Ω RonB = = 804 Ω 80.1µA 80.1µA For the 00101 case, RonE = 64.4mV = 804 Ω. 80.1µA For the 01110 case, RonC = 203mV −132mV 132mV − 64.4mV = 886 Ω RonD = = 844 Ω 80.1µA 80.1µA The voltage across a given conducting device is I D Ron . Small variations in Ron are ignored. € ABCDE Y (mV) 2 (mV) 3 (mV) IDD (uA) ABCDE Y (mV) 2 (mV) 3 (mV) IDD (uA) 00000 00001 00010 00011 00100 00101 00110 00111 01000 01001 01010 01011 01100 01101 01110 01111 2.5 V 2.5 V 2.5 V 2.5 V 2.5 V 130 2.5 V 130 2.5 V 2.5 V 2.5 V 2.5 V 2.5 V 130 200 114 0 0 0 0 0 0 2.5 V 64 0 0 0 0 0 0 64 21 0 0 0 0 2.5 V 64 2.5 V 64 0 0 0 0 2.5 V 64 130 43 0 0 0 0 0 80.1 0 80.1 0 0 0 0 0 80.1 80.1 80.1 10000 10001 10010 10011 10100 10101 10110 10111 11000 11001 11010 11011 11100 11101 11110 11111 2.5 V 2.5 V 2.5 V 200 2.5 V 130 2.5 V 100 130 130 130 110 130 66 110 65 2.5 V 2.5 V 2.5 V 130 2.5 V 130 2.5 V 83 64 64 64 43 64 32 64 32 0 0 2.5 V 64 2.5 V 64 2.5 V 64 0 0 64 22 64 32 87 32 0 0 0 80.1 0 80.1 0 80.1 80.1 80.1 80.1 80.1 80.1 80.1 80.1 80.1 5 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 334 2.5V (80µA) Pav = = 0.100 mW 2 Page 335 2 ( ) F (2.5V ) (3.2x10 Hz ) = 2x10 PD = 10-12 F (2.5V ) 32x106 Hz = 2x10−4W = 200 µW or 0.200 mW € € PD = 10-12 2 9 W = 0.02 W or 20 mW −4 Page 336 The inverter in Fig. 6.38(a) was designed for a power dissipation of 0.2 mW. To reduce the power by a factor of two, we must reduce the W/L ratios by a factor of 2. W  1  1  W  1 1  4.71 2.36 |   =    =  = = 1  L  L 2  1.68  3.36  L S 2  1  −−− 4mW , we must increase the W/L ratios by a factor of 20. 0.2mW W   2.22  44.4 |   = 20 = 1  L S  1  To increase the power by a factor of W   1.81 36.2   = 20 = 1  L L  1  −−− To reduce the power by a factor of three, we must reduce the W/L ratios by a factor of 3. W  1  1.81 0.603 W  W  1 1  3.33 1.11 1  6.66  2.22 = |   =  |   =    =  = = = 1 1.66 1 1  L L 3  1   L A 3 1   L  BCD 3  1  € 6 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 339 t r = 2.2RC = 2.2 28.8x103 Ω 2x10−13 F = 12.7 ns ( )( ( ) )( ) τ PLH = 0.69RC = 0.69 28.8x103 Ω 2x10−13 F = 3.97 ns −−  t   VH + VL  vO (t ) = VF − (VF − VI ) exp −  | vO (τ PHL ) = VH − 0.5  = 2.5 −1.15 = 1.35 V  RC   2   τ  1.35 = 0.2 − (0.2 − 2.5) exp − PHL  → τ PLH = −RC ln 0.5 = 0.69RC  RC  vO (t1 ) = VH − 0.1(VH + VL ) = 2.5 + 0.23 = 2.27 V  t  2.27 = 0.2 − (0.2 − 2.5) exp − 1  → t1 = −RC ln 0.9  RC  vO (t2 ) = VL + 0.1(VH + VL ) = 0.2 + 0.23 = 0.43 V  t  0.43 = 0.2 − (0.2 − 2.5) exp − 2  → t2 = −RC ln 0.1  RC  t f = t2 − t1 = −RC ln 0.1+ RC ln 0.9 = RC ln 9 = 2.2RC € Page 343 t f = 3.7 2.37x103 Ω 2.5x10−13 F = 2.19 ns | τ PHL = 1.2 2.37x103 Ω 2.5x10−13 F = 0.711 ns tr ( )( ) = 2.2(28.8x10 Ω)(2.5x10 F ) = 15.8 ns τP = 3 −13 ( | τ PLH )( ) = 0.69(28.8x10 Ω)(2.5x10 F ) = 4.97 ns 3 −13 0.711 ns + 4.97 ns = 2.84 ns 2 Page 346 € ( ) T = 2Nτ P 0 = 2(401) 10−9 s = 802 ns | f = 1 1 = = 1.25 MHz T 802ns € 7 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 347 For our Psuedo NMOS inverter with VL = 0.2 V , τ PHL = 1.2RonS C = 1.2 Cox" WL L2 = 1.2 W µn (VGS − VTN ) µnCox" VGS − VTN ) ( L −9 τ PHL 2 2 (250x10 m) (100cm m) = 0.606 ps = 1.2 (500cm V − s)(3.3 − 0.825)V (250x10 m) (100cm m) = 2.63 ps L = 1.2R C = 1.2 = 1.2 0.4µ (V − V ) (125cm V − s)(3.1− 0.825)V 2 −9 2 τ PLH onL p τP = GS 2 2 2 TN 0.606 ps + 2.63 ps = 1.62 ps 2 Page 349 € The PMOS transistor is saturated for vO = VL. Pav = 2.5V (1.71mA) 2 I DD = 2 40x10−6  23.7    −2.5 − (−0.6) = 1.71 mA 2  1 L [ ] 2 1  = 2.14 mW | PD = 5x10−12 F (2.5V − 0.2V )   = 13.2 mW  2x10−9 s  −−−  20 pF  2ns  We must increase the power by a factor of    = 8,  5 pF  1ns  so the W/L ratios must also be increased by a factor of 8. W   23.7  190 W   47.4  379 2 1  |   = 8 | PD = 20x10−12 F (2.5V − 0.2V )  −9  = 106 mW   = 8 = = 1  L L  1  1  L S  1   10 s  € 8 ©R. C. Jaeger and T. N. Blalock 08/12/10 CHAPTER 7 Page 370 (a )  20  µA K p = 40x10−6   = 800 2 V 1 ( b) V (c) V €  20  µA mA | Kn = 100x10−6   = 2000 2 = 2.00 2 V V 1 ( ) TN = 0.6 + 0.5 2.5 + 0.6 − 0.6 = 1.09 V TP = −0.6 − 0.75 2.5 + 0.7 − 0.7 = −1.31 V ( ) Page 372 (a ) For vI = 1 V , VGSN − VTN = 1− 0.6 = 0.4V and VGSP − VTP = −1.5 + 0.6 = −0.9V MN is saturated for vO ≥ 0.4 V. MP is in the triode region for vO ≥ 1.6 V. ∴ 1.6 V ≤ v O ≤ 2.5 V (b) M (c) M P is saturated for vO ≤ 1.6 V. ∴ 0.4 V ≤ v O ≤ 1.6 V N is in the triode region for vO ≤ 0.4 V. MP is saturated for v O ≤ 1.6 V. ∴ 0 ≤ v O ≤ 0.4 V −−− W   10  25 Kn  W    =   = 2.5  =  L P K p  L  N 1 1 € Page 373 Both transistors are saturated since VGS = VDS . K 2 2 Kn VGSN − VTN ) = p (VGSP − VTP ) ( 2 2 VGSN = −VGSP → vI = VDD − v I → v I = Kn = K p VTN = VTP VDD 2 10K p 2 K 2 VGSN − VTN ) = p (VGSP − VTP ) → 10 (VGSN − VTN ) = −VGSP + VTP ( 2 2 10 (vI − 0.6) = 4 − v I − 0.6 → vI = 1.273 V Kp 2 10K p 2 VGSN − VTN ) = VGSP − VTP ) → (VGSN − VTN ) = 10 (−VGSP + VTP ) ( ( 2 2 vI − 0.6 = 10 (4 − v I − 0.6) → vI = 2.37 V € 9 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 375 W  Kn   L  N Kn KR = = = 2.5 W  Kp K p   L P VIH = 2KR (VDD − VTN + VTP ) VOL (V DD − KRVTN + VTP ) K −1 ( K −1) 1+ 3K 2(2.5)(2.5 − 0.6 − 0.6) (2.5 − 2.5(0.6) − 0.6) = − = 1.22V 2.5 −1 2.5 −1 1+ 3 2.5 ( ) ( ) ( K + 1)V − V − K V − V = (2.5 + 1)1.22 − 2.5 − 2.5(0.6) + 0.6 = 0.174V = 2K 2(2.5) 2 K (V − V + V ) (V − K V + V ) = − K −1 ( K −1) K + 3 2 2.5 (2.5 − 0.6 − 0.6) (2.5 − 2.5(0.6) − 0.6) = − = 0.902V 2.5 −1 2.5 −1 2.5 + 3 ( ) ( K + 1)V + V − K V − V = (2.5 + 1)0.902 + 2.5 − 2.5(0.6) + 0.6 = 2.38V = R VIH − R R R IH DD R TN TP R VIL R DD R VIL VOH R NM H = VOH TN TP DD DD TP R R IL R TN R TN TP 2 2 − VIH = 2.38 −1.22 = 1.16 V | NM L = VIL − VOL = 0.902 − 0.174 = 0.728 V Page 376 € Symmetrical Inverter : τ P = 1.2RonnC = 1.2 10−12 F ( ) 2 10−4 (2.5 − 0.6) Ω = 3.16 ns Page 377 € Symmetrical Inverter : Ronn = τP 10−9 s = = 167Ω 1.2C 1.2 5x10−12 F ( ) W  1 1 31.5 = =   = ' −4 1  L  N Ronn Kn (VGS − VTN ) 167 10 (2.5 − 0.6) ( ) | W  W  78.8   = 2.5  = 1  L P  L N € 10 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 379 The inverters need to be increased in size by a factor of W   3.77  4.22   = 1.12 = 1  L N  1  | 280ps = 1.12. 250ps W   9.43  10.6   = 1.12 = 1  L P  1  −−− W   3.77  3.3 − 0.75  3.43   =  = 1  L  N  1  3.3 − 0.5  W   9.43  3.3 − 0.75  8.59 |   =  = 1  L  P  1  3.3 − 0.5  Page 380 € τ PHL = 2.4RonnC = 2.4C 2.4C C = = 1.26 Kn Kn (VGS − VTN ) Kn (2.5 − 0.6) τ PLH = 2.4RonpC = 2.4C 2.4C C = = 1.26 Kp K p (VGS − VTN ) K p (2.5 − 0.6) −−− € τ PHL = 2.4RonnC = 2.4C 2.4C C = = 0.94 Kn Kn (VGS − VTN ) Kn (3.3 − 0.75) τ PLH = 2.4RonpC = 2.4C 2.4C C = = 0.94 Kp K p (VGS − VTN ) K p (3.3 − 0.75) Page 381 The inverter in Fig. 7.12 is a symmetrical design, so the maximum current occurs 2 VDD 10-4  2  for vO = v I = . Both transistors are saturated : iDN =  (1.25 − 0.6) = 42.3 µA 2 2  1 2 4x10-5  5  Checking : iDP =  (1.25 − 0.6) = 42.3 µA 2 1 Page 382 € 10 CV 2 (a) PDP ≅ 5DD = F (2.5V ) 2 10 CVDD b PDP ≅ = () 5 F (3.3V ) 2 10 CVDD c PDP ≅ = () 5 F (1.8V ) −13 −13 −13 € 2 5 2 5 5 = 0.13 pJ = 130 fJ = 0.22 pJ = 220 fJ 2 = 0.065 pJ = 65 fJ 11 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 388 Remove the NMOS and PMOS transistors connected to input E, and ground the source of the NMOS transistor connected to input D. The are now 4 NMOS transistors in series, and W   2 8 W  5 |   =   = 4  =  L N  1 1  L P 1 € € Page 392 There are two NMOS transistors in series in the AB and CD NMOS paths, and three PMOS transistors in the ACE and BDE PMOS paths. Therefore : W   2 4 W  W   5  15 2 = 2  = |   = |   = 3  =    L  N − ABCD  1 1  L  N −E 1  L P  1 1 Page 396 (a) The logic network for F = AB + C is B C A ( ) 2 ( ) 2 P = CVDD f = 50x10−12 F (5V ) 10 7 Hz = 12.5 mW € 12 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 400 1  50 pF  2 β =  = 31.6  50 fF  −−− τ P = 31.6τ o + 31.6τ o = 63.2τ o 1 z = e ln z ( ) | z ln z = e ln z 1 ln z =e −−− 1  50 pF  7 β =  = 2.683  50 fF  1, 2.68 , 2.6832 = 7.20, 2.6833 = 19.3, 2.6834 = 51.8, 2.6835 = 139, 2.6836 = 373 A6 = (1+ 3.16 + 10 + 31.6 + 100 + 316) Ao = 462 Ao A7 = (1+ 2.68 + 7.20 + 19.3 + 51.8 + 139 + 373) Ao = 594 Ao € Page 401 From the figure, 10/1 devices give a maximum Ron of 4 kΩ. The W/L ratios must be 4 times W   10  40 larger in order to reduce the maximum Ron to 1 kΩ. ∴   = 4  =  L  1 1 € 13 ©R. C. Jaeger and T. N. Blalock 08/12/10 CHAPTER 8 Page 419 (a ) € NS = 28 • 220 = 211 = 2048 segments | 2 7 • 210 ( b) NS = 230 = 211 = 2048 segments 29 • 210 Page 422 (a) N = 28 • 220 = 228 = 268,435,456 ( b) I DD = 0.05W 15.2mA = 15.2 mA | Current/cell = 28 = 56.4 pA 3.3V 2 cells −−− Reverse the direction of the substrate arrows, and connect the substrates of the PMOS transistors to VDD . € Page 426 MA1 : At t = 0 + , VGS − VTN = 4 V and VDS = 2.5V , so transistor MA1 is operating in the triode region.  1 2.5  i1 = 60x10−6  5 −1− 2.5 = 413 µA 2   1 MA2 : At t = 0 + , VGS = VDS , so transistor MA2 is operating in the saturation region. 2 60x10−6  1 VTN 2 = 1+ 0.6 2.5 + 0.6 − 0.6 = 1.592V i2 =  (5 − 2.5 −1.592) = 24.8 µA 2  1 ( € ) Page 428 MA1 : At t = 0 + , VGS = VDS , so transistor MA1 is operating in the saturation region. 2 60x10−6 1 i1 =  (5 −1) = 480 µA 2  1 MA2 : At t = 0 + , VGS = VDS , so transistor MA2 is operating in the saturation region. 2 60x10−6 1 i1 =  (5 −1) = 480 µA 2  1 € 14 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 431 (a ) At t = 0+ , VGS − VTN = 3 - 0.7 = 2.3 V and VDS = 1.9 V , so transistor MA is operating in the triode region.  1 1.9  i1 = 60x10−6   3 − 0 − 0.7 − 1.9 = 154 µA 2   1 (b) From Table 6.10 : t f = 3.7RonC = 3.7 50x10−15 F = 1.34 ns 60x10−6 (3 − 0.7) −−− VC = VBL − VTN [ )] ( | VC = 3 − 0.7 + 0.5 VC + 0.6 − 0.6 → VC = 1.89 V | VC = 3 − 0.7 = 2.3 V −−− n= −15 CV 25x10 F (1.89V ) = = 2.95 x 105 electrons −19 q 1.60x10 C Page 432 € € VC − VBL 1.9 − 0.95 V − VBL 0 − 0.95 = V = 19.0 mV | ΔV = C = V = −19.0 mV CBL 49CC CBL 49CC +1 +1 +1 +1 CC CC CC CC (a ) ΔV = (b) τ = Ron CC 25 fF = 5kΩ = 0.123 ns CC 1 +1 +1 CBL 49 or τ ≅ RonCC = 5kΩ(25 fF ) = 0.125 ns Page 434 At t = 0 + , VGS − VTN = (3 - 0) - 0.7 = 2.3 V and VDS = 1.5 V , so transistor MA2 is operating in the triode region.  2  1.5  iD = 60x10−6   3 − 0.7 − 1.5 = 279 µA 2  1  € 15 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 436 In setting the drain currents equal, we see that the change in W/L cancels out, and the voltages remain the same.  5 2 1 ∴iD = 60x10-6  (1.33 − 0.7) = 59.5 µA | PD = 2(59.5µA)(3V ) = 0.357 mW 2  1 5 As a check, the current should scale with W/L : iD = (23.5µA) = 58.8 µA 2 −−−  2  2 2 2 1 1 Equating drain currents : 25x10-6  (2.5 − VO − 0.6) = 60x10-6  (VO − 0.6) 2 2  1  1 ( ) ( ) ( ) 1.4VO2 + 0.92VO − 2.746 = 0 → VO = 1.11V  2 2 1 iD = 25x10-6  (2.5 −1.11− 0.6) = 15.6 µA | PD = 2(15.6µA)(2.5V ) = 78.0 µW 2  1  2 2 1 Checking : 60x10-6  (1.11− 0.6) = 15.6 µA 2  1 ( ) ( ) Page 488 € € € Ron = 1 = 23.8 kΩ | τ = 23.8kΩ(25 fF ) = 0.595 ns 60x10 (3 −1.3 −1) −6 Page 440 For all possible input combinations there will be two inverters and 3 output lines in the low state. PD = 5(0.2mW ) = 1.0 mW Page 442 W  2  1.81 1.63   =  = 1  L  L 2.22  1  € 16 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 444 For a 0 - V input, all transistors will be on and the input nodes will all discharge to 0 V. For the 3 - V input, the nodes will all charge to 3 V as long as VTN ≤ 2 V. ( ) VTN = 0.7 + 0.5 3 + 0.6 − 0.6 = 1.26 V. Thus the nodes will all be a 3 V. 2 ≥ 0.7 + γ ( ) 3 + 0.6 − 0.6 → γ ≤ 1.158 −−− The output will drop below VDD / 2. For the PMOS device, VGS − VTP = 3 −1.9 − 0.7 = 0.4V. The PMOS transistor will be saturated. For the NMOS device, VGS − VTP = 1.9 − 0.7 = 1.2V. Assume linear region operation.   2 40x10-6  5 VO  -6 2  (−1.1+ 0.7) = 100x10  1.9 − 0.7 − VO 2  1 2  1  VO2 − 2.4VO + 0.16 = 0 → VO = 68.6 mV € 17 ©R. C. Jaeger and T. N. Blalock 08/12/10 CHAPTER 9 Page 462  0.2V   0.3V   0.4V  iC 2 iC 2 iC2 3 5 6 = exp = exp = exp  = 2.98 x 10 |  = 1.63 x 10 |  = 8.89 x 10 iC1 0.025V i 0.025V i 0.025V       C1 C1 € € Page 464 The current must be reduced by 5 while the voltages remain the same. 300µA I EE = = 60 µA | RC = 5(2kΩ) = 10 kΩ 5 Page 465 I IB = E βF + 1 | IB3 = 92.9µA 107µA = 4.42 µA | I B 4 = = 5.10 µA 21 21 I B3 RC = 4.42µA(2kΩ) = 8.84 mV << 0.7 V | I B 4 RC = 5.10µA(2kΩ) = 10.2 mV << 0.7 V € Page 467 VH = 0 − 0.7 = −0.7 V | VL = 0 − 0.2mA(2kΩ) − 0.7V = −1.1 V VREF = −0.7V + (−1.10V ) 2 = −0.9 V | ΔV = -0.7V - (1.1V ) − 0.4 V Page 469 € NM H = NM L =   0.4  0.4V − 0.025V 1+ ln −1 = 0.107 V 2  0.025   € 18 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 471 P = 3.3V (0.3mA + 0.2mA) = 1.65 mW | P = 3.3V (0.357mA + 0.2mA) = 1.84 mW NM H = NM L =   0.6  0.6V − 0.025V 1+ ln −1 = 0.20 V 2  0.025   −−− From the graph, the VTC slope is -1 for VIL = −1.08 V , VOH = −0.71 V and VIH = −0.91 V , VOL = −1.28 V. NM H = −0.71− (−0.91) = 0.20 V. NM L = −1.08 − (−1.28) = 0.20 V −−− The voltages remain the same. Thus the currents must be reduced by a factor of 3, and the resistor values must be increase by a factor of 3. --REE = −1.7V − (−5.2V ) 0.20mA = 17.5 kΩ | I E = −1.4V − (−5.2V ) 18 kΩ = 0.211 mA | RC1 = 0.4V = 1.90 kΩ 0.211mA Page 472 € For all inputs low : I EE = −1− 0.7 − (−5.2) V = 299µA 11.7 kΩ ΔV = VH − VREF = −0.7 − (−1) = 0.3 V | ΔV = 0.6 V | 2 For an inputs high : I EE = RC 2 = 0.6V = 2.00 kΩ 299µA −0.7 − 0.7 − (−5.2) V 0.6V = 325µA | RC1 = = 1.85 kΩ 11.7 kΩ 325µA Based upon analysis above, RC = 0.6V = 1.85 kΩ 325µA Page 473 € For all inputs low : I EE = −1− 0.7 − (−5.2) V = 299µA 11.7 kΩ ΔV = VH − VREF = −0.7 − (−1) = 0.3 V | ΔV = 0.6 V 2 € | RC = 0.6V = 2.00 kΩ 299µA Page 474 VE − (−VEE ) 0 − 0.7 − (−5.2V ) V RE = = = 15.0 kΩ 0.3mA 0.3 mA € 19 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 475 (a ) € For I E = 0, vO = −5.2 V. ( b) For I E = 0, vO = − - 5.2V 10kΩ = −2.08 V 10kΩ + 15kΩ Page 476 The transistor's power dissipation is  50  P = VCB IC + VBE I E = 5V 2.55mA  + 0.7V (2.55mA) = 14.3 mW 51   The total power dissipation in the circuit is  50  P = VCC IC + VEE I E = 5V 2.55mA  + 5V (2.55mA) = 25.3 mW 51   For vO = −3.7V , I E = −3.7 − (−5) 1300 −0.7 − (−5) − 3.7 = 260 µA. 5000 0.7 = 3.17 mA 1300 5000 The transistor's power dissipation is  50  P = VCB IC + VBE I E = 5V 3.17mA  + 0.7V (3.17mA) = 17.8 mW 51   --10kΩ (a ) − 4V = −5.2V 10kΩ + R → RE = 3.00 kΩ E At the Q - point, I E = ( b) IE = − −4 − (−5.2) 4 − (−5.2) 5.2V 4 4 = 1.73 mA | I E = − = 0 | IE = + = 3.47 mA 3kΩ 3000 10000 3000 10000 Page 478 Increase the value of each resistor by a factor of 10. € € Page 481 ΔV 0.6V RC = = = 1.2 kΩ | τ P = 0.69(1.2kΩ)(2 pF ) = 1.66 ns I EE 0.5mA P = 5.2V (0.5 + 0.1+ 0.1)mA = 3.64 mW | PDP = 6.0 pJ € 20 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 483 RC2 = RC1 = 0 − VL 0.4V = = 800 Ω | P = I EEVEE = 0.5mA(2.8V ) = 1.40 mW I EE 0.5mA PDP = 1.4mW (50 ps) = 70 fJ −−− I EF = I EE = 250 µA | P = I EEVEE = 0.25mA(2.8V ) = 0.70 mW 2 −−− VH = 0 | VL = −0.2 V | VBias = 0.1 V | VBH = −0.7 | VBL = −0.9 V | VBiasB = −0.8 V VAH = −1.4 | VAL = −1.6 V | VBiasA = −1.5 V −VEE = VAH − 0.7V − 0.7V = −1.4 − 0.7 − 0.7 = −2.8 V | VEE = 2.8 V −−− VH = 0 V , VL = −0.4 V , : The C - level bias is VBiasC = VH + VL = −0.2 V 2 Using the level shifter in Fig. 9.27, VBH = −0.7 | VBL = −1.1 V | VBiasB = −0.9 V VAH = −1.4 | VAL = −1.8 V | VBiasA = −1.6 V −VEE = VemitterA − 0.7V = −0.7 = −2.8 V | VEE = 2.8 V € Page 488 For vO = VH , IC = 0, and P = 0. P = VDD I DD = 5V (2.43mA) = 12.1 mA Increase R by a factor of 10 : R = 10(2kΩ) = 20kΩ. Page 490 €  0.1  Γ = exp  = 48.2  0.0258   20  1+  10 A  0.1(48.2)  10 A | IB ≥ = 3.34 A | β FOR = = 3.00 11  20  3.34 A  1−  48.2   −−− αR = 0.2 1 = 0.2 + 1 6  20  1+  10 A  0.2(54.6)  | IB ≥ = 1.59 A  6 20   1−  54.6   Page 491 € 21 ©R. C. Jaeger and T. N. Blalock 08/12/10  20  1+   0.15  10 A  0.1(403)  Γ = exp = 0.769 A  = 403 | I B ≥ 11  20   0.025   1−  403   −−− VT = 1.38x10−23 (273 + 150) 1.60x10−19  0.05 + 1 = 36.5 mV | VCEMIN = 36.5mV ln  = 111 mV  0.05  −−−  0.1  0.25 1 Γ = exp =  = 54.6 | α R = 1+ 0.25 5  0.025    40 1+  10mA  0.25(54.6)  10mA IB ≥ = 1.08 mA | β FOR = = 9.24   5 40 1.08mA  1−  54.6   € 22 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 494    1mA − I  1mA − I BR BR 1ns = 6.4ns ln → I BR = −5.49 mA  | 1.169 = 2.5mA 0.0614mA − I BR  − I BR   40.7  −−−  V −V 5−0 2.5mA  iCMAX = CC CE ≅ = 2.5mA | QXS = 6.4ns1mA −  = 6.01 pC βF 2500 40.7   QF = iF τ F = 2.5mA(0.25ns) = 0.625 pC | QXS >> QF Page 495 € 5 − 0.95 = −1.01 mA | VBE2 = VL + VCESAT1 4000 Using the value of VCESAT in Fig. 9.32, VBE2 = 0.15 + 0.04 = 0.19 V  2 + 1 A better estimate is VCESAT1 = 25mV ln  = 10.1 mV  2  VBE2 = 0.15 + 0.010 = 0.16 V For vI = VL = 0.15 V : iIL = − Page 496 € For vI = VH = 5 V : 5 −1.5 = 1.75 mA | VBE2 = 0.8 V 4000  2 0.875mA + 1− (2.4mA)  3 = 0.025V ln = 0.729 V  1  2  −15 10 A + 1−  40  3  iIH = 2 Using Eq. (5.29), VBESAT Page 499 € 5 −1.5 = 0.875mA 4000 3.5V | βR ≤ = 0.2 10(2kΩ)(0.875mA) 5V - N (2kΩ)β R I B ≥ 1.5V | I B = βR ≤ 3.5V = 0.4 5(2kΩ)(0.875mA) Page 500 € I B2 = (2 + 1) 5 −1.5 = 2.63 mA | 4000 2.43mA + N (1.01mA) ≤ 28.3(2.63mA) → N ≤ 71 € 23 ©R. C. Jaeger and T. N. Blalock 08/12/10 Page 501 vI = VL and vO = 0 : I B 4 = 5 − VB 4 5 − (0 + 0.7 + 0.7) = = 2.25 mA | I L = 41I B 4 = 92.3 mA 1600 1600 IL − 0.7 − 0.7 ≥ 3 → I L ≤ 15.4 mA 41 5 − (3 + 0.7 + 0.7) IB4 = = 0.375 mA | I L = 41I B 4 = 15.4 mA 1600 VCE = 5 −130ΩIC − VO = 5V −130Ω(15.4mA) − 3.7 = −0.702 V 5 −1600 Oops! - the transistor is not in the forward - active region. Assume saturation with VCESAT = 0.15V. I L = I B + IC = € 5 − (0.8 + 0.7 + 3.0) 1600 + 5 − (0.15 + 0.7 + 3) 130 = 9.16 mA Page 513 (a ) BiCMOS NAND gate : Replace the CMOS NOR - gate with a two - input CMOS NAND - gate, and connect its output to the bases of Q3 and Q 4. (b) BiNMOS NAND gate : Replace the input CMOS NOR - gate with a two - input CMOS NAND - gate, and connect M6 and M 7 in series instead of parallel. € 24 ©R. C. Jaeger and T. N. Blalock 08/12/10 Microelectronic Circuit Design Fourth Edition - Part III Solutions to Exercises Updated - 09/25/10 CHAPTER 10 Page 534 (a) AP = Av Ai = 4x104 2.75x108 = 1.10x1013 ( ) Vo 25.3V = = 5.06x103 Vi 0.005V ( b) Vo = 2Po RL = 2(20W )(16Ω) = 25.3 V | Av = Io = Vo 25.3V Vi 0.005V I 1.58 A = = 1.58 A | I i = = = 0.167µA | Ai = o = = 9.48x106 RL 16Ω RS + Rin 10kΩ + 20kΩ I i 0.167µA AP = 25.3V (1.58 A) Po = = 4.79x1010 | Checking : Ap = 5.06x103 9.48x106 = 4.80x1010 PS 0.005V (0.167µA) ( )( ) −−− ( ) ( ) AvdB = 20 log(5060) = 74.1 dB | AidB = 20 log 9.48x106 = 140 dB | APdB = 10 log 4.80x1010 = 107 dB −−− ( ) ( ) ( ) AvdB = 20 log 4x10 4 = 92.0 dB | AidB = 20 log 2.75x108 = 169 dB | APdB = 10 log 1.10x1013 = 130 dB Page 541 € Gin = g11 = 1 = 0.262 µS | A = g21 = 0.262µS (76)(50kΩ) = 0.995 20kΩ + 76(50kΩ) −1 Rout  1 1 75  g22 262Ω = g22 =  + + =− = −0.0131  = 262 Ω | g12 = −  50kΩ 20kΩ 20kΩ (20kΩ) (20kΩ) Rin = € 1 1 = 3.82 MΩ | A = g21 = 0.995 | Rout = = 262 Ω g11 g22 1 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 547 (a ) The constant slope region spanning a maximum input range is between - 0.5 V ≤ vID ≤ 1.5 V , and the bias voltage VID should be centered in this range : VID = vID = VID + vid 1.5 + (−0.5) V = +0.5 V. 2 | - 0.5V ≤ 0.5V + vid → v id ≥ −1 V and 0.5V + vid ≤ 1.5 → v id ≤ +1 V ∴−1 V ≤ vid ≤ +1 V or vid ≤ 1 V and v o ≤ 10 V (b) For VID = −1 V , the slope of the voltage transfer characteristics is zero, so A = 0. −−− vO = 10(vID − 0.5V ) = 10(−0.5 + 0.25 + 0.75sin1000πt ) = (−2.5 + 7.5sin1000πt ) V | VO = −2.5 V € € € Page 552 10V 10V vid = = 0.100V = 100 mV | v id = 4 = 0.001 V = 1.00 mV 100 10 10V vid = 6 = 1.00x10−5 V = 10.0 µV 10 Page 554 360kΩ Av = − = −5.29 | vo = −5.29(0.5V ) = −2.65 V 68kΩ 0.5V ii = = 7.35 µA | io = −i2 = −ii = −7.35 µA 68kΩ Page 556 2V II = = 426 µA | I2 = I I = 426 µA | IO = −I2 = −426 µA 4.7kΩ 24kΩ Av = − = −5.11 | VO = −5.11(2V ) = −10.2 V 4.7kΩ Page 558 € Atr = −R2 = − 5V = −0.2 MΩ | R2 = 200 kΩ 25µA ( ) vo = −R2ii = −2x105 5x10−5 sin 2000πt = −10sin 2000πt V € 2 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 560 36kΩ −3.80V Av = 1+ = +19.0 | vo = 19.0(−0.2V ) = − 3.80 V | io = = −100 µA 2kΩ 36kΩ + 2kΩ −−− 39kΩ Av = 1+ = +40.0 | AvdB = 20 log(40.0) = 32.0 dB | Rin = 100kΩ ∞ = 100kΩ 1kΩ 10.0V vo = 40.0(0.25V ) = 10.0 V | io = = 0.250 mA 39kΩ + 1kΩ −−− 54 20 Av = 10 = 501 R1 + R2 ≥ 100kΩ 1+ R2 = 501 R1 R2 = 500 R1 io = 501R1 ≥ 100kΩ → R1 ≥ 200 Ω vo R2 + R1 10 ≤ 0.1 mA R2 + R1 There are many possibilities. ( R1 = 200 Ω, R2 = 100 kΩ), but ( R1 = 220 Ω, R2 = 110 kΩ) is a better solution since resistor tolerances could cause io to exceed 0.1 mA in the first case. Page 563 € 30kΩ = −20.0 | Rin = R1 = 1.5 kΩ 1.5kΩ v −3.00V vo = −20.0(0.15V ) = −3.00 V | io = o = = −100 µA R2 30kΩ Inverting Amplifier : Av = − Non - Inverting Amplifier : Av = 1+ vo = 21.0(0.15V ) = 3.15 V | io = 30kΩ v 0.15V = +21.0 | Rin = i = =∞ 1.5kΩ ii 0A vo 3.15V = = 100 µA R2 + R1 30kΩ + 1.5kΩ −−− Add resistor R3 in parallel with the op amp input as in the schemeatic on page 560 with R3 = 2 kΩ. € Page 564  3kΩ   3kΩ  Vo1 = 2V  −  = −6V | Vo2 = 4V  −  = −6V | vo = (−6sin1000πt − 6sin 2000πt ) V  1kΩ   2kΩ  v v The summing junction is a virtual ground : Rin1 = 1 = R1 = 1 kΩ | Rin2 = 2 = R2 = 2 kΩ i1 i2 I o1 = Vo1 −6V V −6V = = −2mA | I o2 = o2 = = −2mA | io = (−2sin1000πt − 2sin 2000πt ) mA R3 3kΩ R3 3kΩ € 3 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 567 Since i+ = 0, I2 = 3V = 27.3 µA 10kΩ + 100kΩ −−− 100kΩ V − V V − V+ = −10.0 | VO = −10(3V − 5V ) = +20.0 V | IO = O − = O 10kΩ 100kΩ 100kΩ R4 100kΩ V+ = V2 =5 = 4.545V R3 + R4 10kΩ + 100kΩ Av = − IO = € 20.0 − 4.545 5V = +155 µA | I2 = = 45.5 µA 100kΩ 10kΩ + 100kΩ Page 568 36kΩ V − V V − V+ Av = − = −18.0 | VO = −18(8V − 8.25V ) = 4.50 V | IO = O − = O 2kΩ 36kΩ 36kΩ R2 36kΩ 4.50 − 7.816 V+ = V2 = 8.25 = 7.816 V | IO = = −92.1 µA R1 + R2 2kΩ + 36kΩ 36kΩ Page 570 € € 2π x 106 Av ( s) = − = s + 5000π −400 5000π → Amid = −400 | f H = = 2.50 kHz s 2π 1+ 5000π BW = f H − f L = 2.50 kHz − 0 = 2.50 kHz | GBW = (400)(2.50kHz) = 1.00 MHz Page 572 1 1 fH = = 804 kHz 2π 1kΩ 100kΩ (200 pF ) ( ) Page 573 250 250π 1+ s € Av ( s) = € Page 575 1 1 fL = = 15.8 Hz 2π 1kΩ 100kΩ (0.1µF ) ( | Ao = 250 | f L = 250π = 125 Hz | f H = ∞ | BW = ∞ −125 = ∞ 2π ) € 4 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 577 −1+ 4 150 = −1+ 2 + j2 1+ j2 Av ( j1) = 50 Av ( j1) = | 150 2 (1) + (2) 2 = 67.08  2 A vdB = 20 log(67.08) = 36.5 dB | ∠Av ( j1) = ∠(50) + ∠(3) − tan −1  = 0 + 0 − 63.4 o = −63.4 o  1 Av ( j5) = 50 −25 + 4 1050 = −25 + 2 + j10 23 − j10 Av ( j5) = | 1050 2 (−23) + (10) 2 = 41.87  10  o o AvdB = 20 log(41.87) = 32.4 dB | ∠Av ( j5) = ∠(1050) + − tan −1  = 0 − −23.5 = +23.5  −23 ( ) −−− A v ( jω ) = 20 0.1ω 1+ j 1− ω 2 20 Av ( j0.95) = | 2 12 + (0.1) (0.95 ) = 14.3 2 (1− 0.95 ) 2 2 0.1(0.95)  = 0 − 44.3o = −44.3o ∠Av ( j0.95) = ∠20 − tan −1 2  1− 0.95   0.1(1)  20 −1  = 0 − 90 o = −90.0 o Av ( j1) = = 0 | ∠Av ( j1) = ∠20 − tan  2 2 2  1−1  0.1) 1 ( 2 1 + 2 1−12 ( ) ( ) ( ) ( ) 20 Av ( j1.1) = 2 12 + ( ) (1−1.1 )  0.1(1.1)   = 0 − −27.6 o = +27.6 o | ∠Av ( j1.1) = ∠20 − tan−1 2  1−1.1  ( = 17.7 (0.1) 1.12 2 ) 2 −−− −400 100  s  1+ 1+  s  50000   (i ) A (s) =  v fL = | Ao = 400 or 52 dB 100 50000 = 15.9 Hz | f H = = 7.96 kHz | BW = 7960 −15.9 = 7.94 kHz 2π 2π € 5 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 577 2x10 7 s −400 = (s + 100)(s + 50000) 1+ 100 1+ s  s  50000    ω   ω     100  −1 o −1 100 −1 ∠Av ( jω ) = −180 + 90 o − tan −1  − tan   = −90 − tan   − tan   100   50000   100   50000  Av ( s) = − ∠Av ( j0) = −90 − 0 − 0 = −90 o  100   100  −1 o ∠Av ( j100) = −90 o − tan−1  − tan   = −90 − 45 − 0.57 = −136  100   50000   50000    −1 50000 o ∠Av ( j50000) = −90 o − tan−1  − tan   = −90 − 89.9 − 45 = −225  100   50000  ∠Av ( j∞) = −90 − 90 − 90 = −270 o € Page 581 26 R2 Av = − = −10 20 = −20.0 | R1 = Rin = 10 kΩ R1 R2 = 20R1 = 200 kΩ | C = 1 = 265 pF 2π (3kHz)(200kΩ) Closest values : R1 = 10 kΩ | R2 = 200 kΩ | C = 270 pF € Page 582 20 R2 Av = − = −10 20 = −10.0 | R1 = Rin = 18 kΩ R1 R2 = 10R1 = 180 kΩ | C = 1 1 = = 1.77 nF = 1770 pF ω L R1 2π (5kHz)(18kΩ) Closest values : R1 = 10 kΩ | R2 = 180 kΩ | C = 1800 pF Page 583 € Rin = R1 = 10 kΩ | ΔV = − vO 2 (10V 2)  1  1ms = 0.05 µF I ΔT | C =  ( ) C 10kΩ  10V  4 6 8 t (msec) € -10V 6 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 567 vO = −RC dv I = −(20kΩ)(0.02µF )(2.50V )(2000π )(cos2000πt ) = −6.28cos2000πt V dt € 7 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 11 Page 605 1 AvIdeal = = 100 β | T = Aβ = 105 = 1000 100 vo = Av v i = 99.9(0.1V ) = 9.99 V | vid = | Av = AvIdeal T 1000 = 100 = 99.90 1+ T 1001 v o 9.99V = = 99.9 µV A 105 −−− AvIdeal = − R2 R1 Av = AvIdeal | 1 R R = 1+ 2 → 2 = 99 β R1 R1 | AvIdeal = −99 | T = Aβ = 105 = 1000 100 T 1000 = −99 = −98.90 1+ T 1001 vo = Av v i = −98.9(0.1V ) = −9.89 V | v id = vo −9.89V = = −98.9 µV A 105 −−− Values taken from OP - 27 specification sheet (www.jaegerblalock.com or www.analog.com) −−− Values taken from OP - 27 specification sheet (www.jaegerblalock.com or www.analog.com) € Page 606 1 R 39kΩ AvIdeal = = 1+ 2 = 1+ = +40.0 β R1 1kΩ FGE = 1 = 0.00398 or 0.398 % 1+ T | T = Aβ = | FGE ≅ 10 4 = 250 40 | Av = AvIdeal T 250 = 40 = 39.8 1+ T 251 1 = 0.40 % T −−− AvIdeal = − R2 39kΩ =− = −39.0 R1 1kΩ Av = AvIdeal | β= 1 1 = R 40 1+ 2 R1 | T = Aβ = 10 4 = 250 40 T 250 1 = −39 = −38.8 | FGE = = 0.00398 or 0.398 % 1+ T 251 1+ T | | FGE ≅ 1 = 0.40 % T € 8 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 608 Values taken from OP - 77 specification sheet (www.jaegerblalock.com or www.analog.com) € Page 609 1 R 50Ω 1+ T = o → T = −1 = 499 | A = T   = 499( 40) = 2.00x10 4 Rout 0.1Ω β  −−− Av = AvIdeal T 1+ T T = Aβ = 10 4 | AvIdeal = 1+ R2 39kΩ = 1+ = +40.0 R1 1kΩ 1kΩ = 249.7 0.05kΩ + 39kΩ + 1kΩ | Av = AvIdeal T 249.7 = 40 = 39.8 1+ T 250.7 --Avmax = 1+ Avmin = 1+ € € 39kΩ(1.05) 1kΩ(0.95) 39kΩ(0.95) 1kΩ(1.05) = 44.1 | GE = 44.2 − 40.0 = 4.20 | FGE = = 36.3 | GE = 36.3 − 40.0 = −3.70 FGE = 4.20 = 10.5 % 40 −3.70 = −9.3 % 40 Page 610 1 R 200Ω 1+ T = o → T = −1 = 1999 | A = T   = 1999(100) = 2.00x10 5 or 106 dB Rout 0.1Ω β  Page 612 Values taken from op - amp specification sheets (www.jaegerblalock.com or www.analog.com) Page 613 € 9 ©R. C. Jaeger and T. N. Blalock 09/25/10   10kΩ 1MΩ 10 4 = Rin = Rid (1+ T ) | T = Aβ = 10 4   40.39 = 248 | Rin = 1MΩ [1+ 248] = 249 MΩ 10kΩ 1MΩ + 390kΩ   vi 1V βv T 248 =− = −4.02 nA | i1 = o | vo = AvIdeal v i = 40 vi = 39.8v i Rin 249 MΩ R1 1+ T 249 βv 39.8  1V  i1 = o =   = 98.5 µA | Yes, i1 >> i− R1 40.4  10kΩ    10 4 10kΩ If we assume 1MΩ >> 10kΩ, T = Aβ = 10 4  = 250 | Rin = 1MΩ [1+ 250] = 251 MΩ = 10kΩ + 390kΩ  40 i− = − vi 1V βv T 250 =− = −3.98 nA | i1 = o | vo = AvIdeal v i = 40 vi = 39.8v i Rin 251MΩ R1 1+ T 251 βv 39.8  1V  i1 = o =   = 99.5 µA | Yes, i1 >> i− R1 40  10kΩ  i− = − € Page 614 Rin ≅ R1 + Rid R2 100kΩ = 1kΩ + 1MΩ = 1001 Ω | Rinideal = R1 = 1000 Ω | 1 Ω or 0.1 % 1+ A 1+ 10 5 Page 622 € 10 ©R. C. Jaeger and T. N. Blalock 09/25/10 AvIdeal = 1+ R2 91kΩ = 1+ = 10.1 R1 10kΩ RinD = Rid + R1 ( R2 + Ro ) = 25kΩ + 10kΩ (91kΩ + 1kΩ) = 34.0 kΩ [ ] [ ] D Rout = Ro R2 + R1 Rid = 1kΩ 91kΩ + 10kΩ 25kΩ = 990 Ω T = Ao R1 Rid Ro + R2 + R1 Rid = 10 4 10kΩ 25kΩ 1kΩ + 91kΩ + 10kΩ 25kΩ = 720 T 720 = 10.1 = 10.1 1+ T 1+ 720 Rin = RinD (1+ T ) = 34.0kΩ(1+ 720) = 24.5 MΩ Av = AvIdeal Rout = D Rout 990Ω = = 1.37 Ω 1+ T 1+ 720 −−− AvIdeal = 1+ R2 91kΩ = 1+ = 10.1 R1 10kΩ ( ) ( ) [ R + R ( R + R )] = 5kΩ 1kΩ [91kΩ + 10kΩ (25kΩ + 2kΩ)] = 826 Ω RinD = RI + Rid + R1 R2 + Ro RL = 2kΩ + 25kΩ + 10kΩ 91kΩ + 1kΩ 5kΩ = 36.0 kΩ D Rout = RL Ro 2 1 id I   RL R1 5kΩ 10kΩ vth =  Ao vid  = 10 4 v id = 818v id 1kΩ + 5kΩ 1kΩ 5kΩ + 91kΩ + 10kΩ  Ro + RL  RL Ro + R2 + R1 ( ) ( ) Rth = R1 R2 + RL Ro = 10kΩ 91kΩ + 1kΩ 5kΩ = 9.02 kΩ v  Rid 25kΩ T = − th  = −818 = −568 9.02kΩ + 25kΩ + 2kΩ  v id  Rth + Rid + RI T 568 = 10.1 = 10.1 1+ T 1+ 568 Rin = RinD (1+ T ) = 36.0kΩ(1+ 568) = 20.5 MΩ Av = AvIdeal Rout = D Rout 826Ω = = 1.45 Ω 1+ T 1+ 568 −−− Continued on next page. € 11 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 622 cont. R 91kΩ AvIdeal = 1+ 2 = 1+ = 10.1 R1 10kΩ D RinD = Rid = 25kΩ | Rout = Ro = 1 kΩ T = Ao R1 10kΩ = 10 4 = 990 R1 + R2 10kΩ + 91kΩ T 990 = 10.1 = 10.1 1+ T 1+ 990 Rin = RinD (1+ T ) = 25.0kΩ(1+ 990) = 24.8 MΩ Av = AvIdeal Rout = D Rout 1kΩ = = 1.01 Ω 1+ T 1+ 990 −−− AvIdeal = 1+ R2 91kΩ = 1+ = 10.1 R1 10kΩ RinD = RI + Rid + R1 ( R2 + Ro ) = 5kΩ + 25kΩ + 10kΩ (91kΩ + 1kΩ) = 39.0 kΩ [ ] [ ] D Rout = Ro R2 + R1 ( Rid + RI ) = 1kΩ 91kΩ + 10kΩ (25kΩ + 5kΩ) = 990 Ω vth = Aov id R1 10kΩ = 10 4 v id = 980v id Ro + R2 + R1 1kΩ + 91kΩ + 10kΩ Rth = R1 ( R2 + Ro ) = 10kΩ (91kΩ + 1kΩ) = 9.02 kΩ T= vth Rid 25kΩ = 980 = 628 vid Rth + Rid + RI 9.02kΩ + 25kΩ + 5kΩ T 628 = 10.1 = 10.1 1+ T 1+ 628 Rin = RinD (1+ T ) = 39.0kΩ(1+ 628) = 24.5 MΩ Av = AvIdeal Rout = D Rout 990Ω = = 1.57 Ω 1+ T 1+ 628 € 12 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 626 RinD = vi = RI Rid ( RF + Ro ) ii | D Rout = vo = Ro RF + Rid RI io ( ) Page 628 AtrIdeal = −RF = −91kΩ € RinD = RI ( RF + Ro ) = 10kΩ (91kΩ + 1kΩ) = 9.02 kΩ D Rout = Ro ( RF + RI ) = 1kΩ (91kΩ + 10kΩ) = 990 Ω T = Ao RI 10kΩ = 10 4 = 980 Ro + RF + RI 1kΩ + 91kΩ + 10kΩ T 980 = −91kΩ = −90.9 kΩ 1+ T 1+ 980 D RinD 9.02kΩ Rout 990Ω Rin = = = 9.19 Ω Rout = = = 1.01 Ω 1+ T 1+ 980 1+ T 1+ 980 −−− Atr = AtrIdeal AtrIdeal = −RF = −91kΩ RinD = Rid ( RF + Ro ) = 25kΩ (91kΩ + 1kΩ) = 19.7 kΩ D Rout = Ro ( RF + Rid ) = 1kΩ (91kΩ + 25kΩ) = 991 Ω T = Ao Rid 25kΩ = 10 4 = 2137 Ro + RF + Rid 1kΩ + 91kΩ + 25kΩ T 2137 = −91kΩ = −91.0 kΩ 1+ T 1+ 2137 RD 19.7kΩ RD 991Ω Rin = in = = 9.21 Ω Rout = out = = 0.464 Ω 1+ T 1+ 2137 1+ T 1+ 2317 Atr = AtrIdeal € 13 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 633 1 1 =− = −10−4 S R 10kΩ D Rin = Rid + R Ro = 25kΩ + 10kΩ 1kΩ = 25.9 kΩ AtcIdeal = − D Rout = Ro + R Rid = 1kΩ + 10kΩ 25kΩ = 8.14 kΩ v  R 25kΩ id T = − th  = 9090 = 8770 0.909kΩ + 25kΩ  v id  Rth + Rid 1 T  1  8770  Atc = −  =−   = −0.100 mS R  1+ T  10kΩ  1+ 8770  Rin = RinD (1+ T ) = 25.9kΩ(1+ 8770) = 227 MΩ D Rout = Rout (1+ T ) = 8.14kΩ(1+ 8770) = 71.4 MΩ Page 637 € AiIdeal = 1+ R2 27kΩ = 1+ = +10 R1 3kΩ ( ) ( ) RinD = Rid R2 + R1 Ro = 25kΩ 27kΩ + 3kΩ 1kΩ = 13.2 kΩ D Rout = Ro + R1 ( R2 + Rid ) = 1kΩ + 3kΩ (27kΩ + 25kΩ) = 3.84 kΩ T = Ao T = 10 4 [ R ( R + R )]  R  id   R1 ( R2 + Rid ) + Ro  R2 + Rid  1 2 id 3kΩ (27kΩ + 25kΩ)   25kΩ   = 3555 1kΩ + 3kΩ (27kΩ + 25kΩ)  27kΩ + 25kΩ   T   3555  Ai = +10  = +10  = +10.0 1+ T   1+ 3555  Rin = RinD 13.2kΩ = = 3.71 Ω (1+ T ) 1+ 3555 D Rout = Rout (1+ T ) = 3.84kΩ(1+ 3555) = 13.7 MΩ € 14 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 638 Rid' = RI Rid = 10kΩ 25kΩ = 7.14 kΩ AiIdeal = 1+ R2 270kΩ = 1+ = +10 R1 30kΩ ( ) ( ) RinD = Rid' R2 + R1 Ro = 7.14kΩ 270kΩ + 30kΩ 1kΩ = 6.96 kΩ ( ) D Rout = Ro + R1 R2 + Rid' = 1kΩ + 30kΩ (270kΩ + 7.14kΩ) = 28.1 kΩ T = Ao T = 10 4 [ R ( R + R )] 1 ( 2 R1 R2 + Rid' ' id )  R'  id   ' R + + Ro  2 Rid  30kΩ (270kΩ + 7.14kΩ)   7.14 kΩ   = 248.5 30kΩ (270kΩ + 7.14kΩ) + 1kΩ  270kΩ + 7.14kΩ   T   248.5  Ai = +10  = +10  = +9.96 1+ T   1+ 248.5  Rin = RinD 6.96kΩ = = 27.9 Ω (1+ T ) 1+ 248.5 D Rout = Rout (1+ T ) = 28.1kΩ(1+ 248.5) = 7.01 MΩ Page 644 € Values taken from op - amp specification sheets (www.jaegerblalock.com or www.analog.com) −−− VO ≤ 50(0.002V ) → −0.100 V ≤ VO ≤ +0.100 V Page 647 € Values taken from op - amp specification sheets (via www.jaegerblalock.com or www.analog.com) −−− R = 39kΩ 1kΩ = 975 Ω R = 1 kΩ is the closest 5% value, or one could use 39 kΩ and 1 kΩ resistors in parallel. −−− V I 1.5mV 100nA v O (t ) = VOS + OS t + B 2 t | 1.5mV + t+ t = 15V → t = 6.00 ms RC C 10kΩ(100 pF ) 100 pF Page 648 € € Values taken from op - amp specification sheets (via www.jaegerblalock.com or www.analog.com) 15 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 650 Values taken from op - amp specification sheets (via www.jaegerblalock.com or www.analog.com) −−− −1  1 1  REQ R1 + R2 ≥  −  = 20kΩ  4kΩ 5kΩ  Including 5% tolerances, R1 + R2 ≥ 21kΩ Av = 10 → R2 = 9R1 20V = RL ( R2 + R1 ) ≥ = 4kΩ 5mA A few possibilities : 27 kΩ and 3 kΩ, 270 kΩ and 30 kΩ, 180 kΩ and 20 kΩ, etc. € € Page 653  v ic  vo = A vid +  CMRR     v ic  5.000  vomin = A vid +  = 25000.002 −  = 3.750 V CMRR  10 4      v ic  5.000  vomax = A v id +  = 2500 0.002 +  = 6.250 V | CMRR  10 4    Page 655   1  1  A1+ 10 41+  4  2CMRR   2x10  Av = = = 1.000   1  1  4 1+ A1−  1+ 10 1− 4  2CMRR   2x10  3.750 V ≤ v O ≤ 6.250 V  1  103 1+ 3  2x10  Av = = 1.000  1  3 1+ 10 1− 3  2x10  Page 656 € GE = FGE ( Av ) ≤ 5x10−5 (1) = 5x10−5 Worst case occurs for negative CMRR : GE ≅ 1 1 + A CMRR 1 = 4 x10 4 or 92 dB 2.5x10−5 −1  1  −5 A =  5x10 −  CMRR   If both terms make equal contributions: A = CMRR = −1  1 −5 For other cases : CMRR =  5x10 −  A  A = 100 dB −1  1  −5 CMRR = 5x10 − 5  = 2.5x10 4 or 88 dB 10   CMRR = 100 dB € € or −1  1  −5 A = 5x10 − 5  = 2.5x10 4 or 88 dB 10   Page 657 Values taken from op - amp specification sheets (via www.jaegerblalock.com or www.analog.com) 16 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 661 Ao = 10 A( s) = 100 20 = 10 5 ( ) 6 ωT 2π 5x10 10 7 π 100π | ωB = = = = 100π | f B = = 50 Hz 5 5 Ao 2π 10 10 ωT 10 7 π = s + ω B s + 100π −−− ωT 2π x 10 6 2π x 10 6 = = ω s + 10π 2π x 10 6 s+ T s+ 5 Ao 2x10 Av ( s) = Page 664 € Ao = 10 90 20 | fB = = 31600 ( ) fT 5x10 6 = = 158 Hz | f H ≅ βfT = 0.01(5 MHz) = 50 kHz Ao 31600 2π 5x10 6 ωT 10 7 π A( s) = = = s + ω B s + 2π (158) s + 316π | Av ( s) = ( 2π 5x10 6 ) ( s + 2π 5x10 4 ) = 10 7 π s + 10 5 π −−− Aβ = ωT βωT 1 β | For ω H >> ω B : Aβ ≅ = = − j1 since ω H = βωT s + ωB jω H j Page 666 90 € fT 5x10 6 5 MHz = = 158 Hz | f H ≅ βfT = = 15.8 kHz 50 Ao 31600 1+ 10 20 2π 5x10 6 2π 5x10 6 10 7 π 10 7 π A( s) = = | Av ( s) = = s + 2π (158) s + 316π s + 3.16x10 4 π s + 2π 15.8x10 3 Ao = 10 20 = 31600 ( | fB = ) ( ( ) ) −−− f H ≅ βfT = 1(10 MHz) = 10 MHz | f H ≅ βfT = 1 (10 MHz) = 5 MHz 2 Page 667 € 100 20 fT 10x10 6 10 MHz 10 MHz = = 100 Hz | f H ≅ βfT = = = 10 kHz 5 60 Ao 1000 10 20 10 7 7 2π 10 2π 10 ωT 2πx10 7 2x10 7 π A( s) = = = | Av ( s) = = s + ω B s + 2π (100) s + 200π s + 2x10 4 π s + 2π 10 4 Ao = 10 = 10 5 | fB = ( ) € ( ) ( ) 17 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 669 SR 5x10 5V / s SR 5x10 5 V / s VM ≤ = = 3.98 V | f M = = = 7.96 kHz ω 2π (20kHz) 2πVFS 2π (10V ) € Page 670 Values taken from op - amp specification sheets (via www.jaegerblalock.com or www.analog.com) Ao = 1.8x10 6 | f T = 8 MHz | ω B = ωT 2π (8 MHz ) 1 = = 8.89π | RC = = s 6 Ao ω B 8.89π 1.8x10 Page 677 € 2   ln100  πζ   | Let κ =  0.01 = exp−  2   π   1− ζ  φ M = tan−1 2ζ ( 4ζ 4 + 1 − 2ζ 2 ) 0.5 | ζ= κ = 0.826 1+ κ = 70.9 o ( ) cos 45o = 4ζ 4 + 1 − 2ζ 2 → ζ = 0.420  πζ  | Overshoot = 100% exp − = 23.4 % 2   1− ζ  −−− Settling within the 10% error bars requires ω nt ≥ 13. ∴ ω n ≥ ω n = ω Bω 2 (1+ Aoβ ) ≅ ω Bω 2 Aoβ = βω T ω 2 13 = 1.3x106 rad / s −5 10 s ( 1.3x106 / 2π f n2 | f2 = ≥ βfT 0.1 10 6 ( ) ) 2 = 428 kHz Page 678 € ∠T ( jω1 ) = −180 o → 3tan −1 T ( jω180 ) = 5 3 = ( ω + 1) ( 2 1 ω1 = 180 → ω1 = 3 1 5 5 8 = | GM = = 1.60 or 4.08 dB 3 8 5 3+1 ) € 18 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 682 From the upper graph, the final value of the first step is 5 mV, and the peak of the response is  9.5mm  5.7mV − 5mV approximately 4mV + 2mV  = 14 %  = 5.7 mV. Overshoot = 100% 5mV  11mm    − ln 0.14  2 πζ  κ  | Let κ =  0.14 = exp− = 0.3917 | ζ = = 0.5305  2  π 1+ κ   1− ζ   2ζ φ M = tan−1 = 54.2 o 0.5 4ζ 4 + 1 − 2ζ 2 ( ) −−− From the lower graph, the final value of the first step is 5 mV, and the peak of the response is  10mm  9.2mV − 5mV approximately 5mV + 5mV  = 84 %  = 9.2 mV. Overshoot = 100% 5mV  12mm    − ln 0.84  2 πζ  κ  | Let κ =  0.84 = exp− = 0.05541  = 0.3080 | ζ = 2  π 1+ κ   1− ζ   2ζ φ M = tan−1 = 6.34 o 0.5 4ζ 4 + 1 − 2ζ 2 ( ) −−− The µA741 curves will be distorted by slew rate limiting. € 19 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 12 Page 700 AvA = AvB = AvC = − R2 68kΩ =− = −25.2 | RinA = RinB = RinC = R1 = 2.7 kΩ R1 2.7kΩ The op - amps are ideal : RoutA = RoutB = RoutC = 0 −−− 3 Av = AvA AvB AvC = (−25.2) = −16,000 | Rin = RinA = 2.7 kΩ | Rout = RoutC = 0 −−− 2 2  2.7kΩ  3 Av = (−25.2)   ≥ 0.99(25.2)  Rout + 2.7kΩ   2.7kΩ  |   ≥ 0.99  Rout + 2.7kΩ  3 2.7kΩ ≥ 0.9950 Rout + 2.7kΩ → Rout ≥ 13.6 Ω Page 705 € Av (0) = 50(25) = 1250 Av (ω H ) = | 1250 2    ω H2 ω H2 1+  1+  = 2 → ω2 H 2 2      (10000π )   (20000π )  = 884 ( ) ω H2 = 6.925x10 8 → ω H = 26.3x10 3 → f H = 2 + 4.935x10 9ω H2 − 3.896x1018 = 0 26.3x10 3 = 4190 Hz 2π −−− Av (0) = −100(66.7)(50) = −3.33x10 5 Av (ω H ) = −3.34 x10 5 2 = −2.36x10 5     ω H2 ω H2 ω H2 1+  1+  1+ =2 2 2 2        (10000π )   (15000π )   (20000π )  ω H6 + 7.156x10 9 ω H4 + 1.486x1010 ω H2 − 8.562x10 27 = 0 Using MATLAB, ω H = 21.7x10 3 → f H = 21.7x10 3 = 3450 Hz 2π −−− 3 Av (0) = (−30) = −2.70x10 4 | 1 3 f H = ( 33.3kHz) 2 −1 = 17.0 kHz € 20 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 711 130kΩ Av1 = 1+ = 6.909 22kΩ 2 | vO1 = 0.001(6.909) = 6.91 mV | vO 2 = 0.001V (6.909) = 47.7 mV 3 4 vO 3 = 0.001(6.909) = 330 mV | vO 4 = 0.001V (6.909) = 2.28 V 5 vO 5 = 0.001V (6.909) = 15.7 V > 15 V. ∴vO5 = VOmax = 15 V vO 6 = 15V (6.909) = 104 V > 15 V. ∴vO6 = VOmax = 15 V Page 714 € VA = V1 + IR2 | VB = V2 − IR2 | I= VA − VB 5.001V − 4.999V = = 1.00 µA 2R1 2kΩ VA = V1 + IR2 = 5.001V + 1.00µA( 49kΩ) = 5.05 V VB = V2 − IR2 = 4.999V −1.00µA( 49kΩ) = 4.95 V  R   10kΩ  VO = − 4 (VA − VB ) =  − (5.05 − 4.95) = −0.100 V  10kΩ   R3  Page 717 € ALP ( s) = For Q = ω o2 ω s 2 + s o + ω o2 Q 1 2 : ALP ( jω ) = | ALP (0) = ω o2 = 1 or 0 dB ω o2 ω o2 −ω 2 + jω 2ω o + ω o2 | ALP ( jω H ) =  1 2 =  2 + 2ω o2ω H2  2  ω o4 2 (ω 2 o − ω H2 ) 2ω o4 = ω o4 + ω H4 → ω H = ω o −−− To increase the cutoff frequency from 5 kHz to 10 kHz while maintaining the resistances 10kHz the same, we must decrease the capacitances by a factor of =2 5kHz 0.02µF 0.01µF ∴ C1 = = 0.01 µF | C2 = = 0.005 µF 2 2 −−− ALP ( jω ) = ω o2 ω −ω 2 + jω o + ω o2 Q | ALP ( jω o ) = ω o2 = − jQ | ω o2 2 2 −ω o + j + ωo Q ALP ( jω o ) = Q € 21 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 718 To decrease the cutoff frequency from 5 kHz to 2 kHz, we must increase the 5kHz resistances by a factor of = 2.50 → R1 = R2 = 2.50(2.26kΩ) = 5.65 kΩ 2kHz 2C R 2 2 1 = = C 2R 2 2 Q= | Q is unchanged. −−− C R1 R2 → R12 + 2R1 R2 + R22 = 2R1 R2 → R12 = −R22 - - can't be done! C R + R 2 1 2  R (R + R )  R1 R2 dQ 1 1 1 1 2   Q= = − R R 1 2 = 0 → R2 = R1 → Qmax = 2 R1 + R2 dR2 ( R + R )  2 R1 R2 2  1 2 1 = Page 719 € AHP ( jω o ) = K −ω o2 K = 2 2 2 −ω o + j (3 − K )ω o + ω o 3 − K | AHP ( jω o ) = K ∠90 o 3− K −−− fo = 1 2π 10kΩ(20kΩ)(0.0047µF )(0.001µF ) = 5.19 kHz −1   20kΩ(1.0nF )  10kΩ 4.7nF + 1.0nF  Q= + (1− 2) = 0.829  20kΩ 4.7nF 1.0nF  10kΩ 4.7nF ( ) ( )   € Page 720 K dQ SKQ = Q dK Q= | Q= 1 3− K | dQ −1 K dQ = −1) = Q 2 | SKQ = = KQ 2 ( dK (3 − K ) Q dK 1 3 → KQ = 3Q −1 SKQ = 3Q −1 = −1 = 1.12 3− K 2 Page 721 € Rth = 2kΩ 2kΩ = 1kΩ | f o = 1 2π 1kΩ(82kΩ)(0.02µF )(0.02µF ) = 879 Hz | Q = 1 82kΩ = 4.53 2 1kΩ € 22 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 726 The lower gain results in a larger gain error and center frequency shift. −−− R 294kΩ ABP ( jω o ) = KQ = 2 | 10 = → R1 = 29.4 kΩ R1 R1 −−− R= 1 1 = = 39.8 kΩ | R2 = QR = 10(39.8kΩ) = 398 kΩ ω oC 2π (2000)(2000 pF ) R2 R1 = ABP ( jω o ) = 398kΩ = 19.9 kΩ | R3 can remain the same. | 20 The nearest 1% values are R = 40.2 kΩ, R2 = 402 kΩ, R1 = 20.0 kΩ, R3 = 49.9 kΩ fo = 1 1 1 1 = = 1.98 kHz | BW = = = 198 Hz 2πRC 2π ( 40.2kΩ)(2nF ) 2πR2C 2π (402kΩ)(2nF ) ABP ( jω o ) = − R2 402kΩ =− = −20.1 R1 20.0kΩ −−− Blindly using the equations at the top of page 580 yields f omin = 1 1 = = 1946 Hz 2πRC 2π (1.01)(29.4kΩ)(1.02)(2.7nF ) f omax = 1 1 = = 2067 Hz 2πRC 2π (0.99)(29.4kΩ)(0.98)(2.7nF ) BW min = 1 1 = = 195 Hz 2πR2C 2π (1.01)(294kΩ)(1.02)(2.7nF ) BW max = 1 1 = = 207 Hz 2πR2C 2π (0.99)(294kΩ)(0.98)(2.7nF ) min ABP =− 294kΩ(1.01) R2 =− = −20.4 R1 14.7kΩ(0.99) max | ABP =− 294kΩ(0.99) R2 =− = −19.6 R1 14.7kΩ(1.01) The W/C results are similar if R and C are not the same for example where ωo = 1 RA RB CACB . € 23 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 727 SCQ1 = R1 R2  C1 Q C1 dQ C1  1 = =  = 0.5 Q dC1 Q 2 C1C2 R1 + R2  Q 2C1 SRQ2 = R2 dQ Q dR2 | R1 = R2 → Q = 1 C1 → SRQ2 = 0 2 C2 −−− SRω o = SKQ = R dω o R  −1  ω C dω o C  −1  ω =  2  = − o = −1 | SCω o = =  = − o = −1 2 ω o dR ω o  R C  ωo ω o dR ω o  RC  ωo K dQ K (−1)(−1) K 2 K = = Q = KQ = 2 Q dK Q (3 − K ) Q 3− K −−− SRω1o = R1 dω o R1  ω o  dRth R1  Rth2  1 R3 = − = −  2=−  ω o dR1 ω o  2Rth  dR1 2Rth  R1  2 R1 + R3 R2 dω o R2  ω o  1 = − =− ω o dR2 ω o  2R2  2 R dω o R3  ω o  dRth R3  Rth2  1 R1 = 3 = − = −  2=−  ω o dR1 ω o  2Rth  dR3 2Rth  R3  2 R1 + R3 SRω2o = SRω3o SCω o = C dω o C  ω o  = −  = −1 ω o dC ω o  C  SRQ1 = R1 dQ R1  Q  dRth R1  Rth2  1 R3 = − = −  2=−  Q dR1 Q  2Rth  dR1 2Rth  R1  2 R1 + R3 R2 dQ R2  Q  1 =  =+ Q dR2 Q  2R2  2 R dQ R3  Q  dRth R3  Rth2  1 R1 SRQ1 = 3 = − = −  2=−  Q dR3 Q  2Rth  dR3 2Rth  R3  2 R1 + R3 SRQ2 = SCQ = C dQ C C dBW C  BW  = (0) = 0 | SCBW = = −  = −1 Q dC Q BW dC BW  C  € 24 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 728 (a ) fo = R1 = R2 = 5(2.26kΩ) = 11.3 kΩ | C1 = 1 fo = = 4980 Hz (11.3kΩ)(11.3kΩ)(0.004µF )(0.002µF ) 11.3kΩ (0.004 µF )(0.002µF ) 2 = = 0.471 2π Q= (b) 0.02µF 0.01µF = 0.004 µF | C2 = = 0.002 µF 5 5 11.3kΩ 0.004µF + 0.002µF 3 R1 = R2 = 0.885(2.26kΩ) = 2.00 kΩ | C1 = 0.02µF 0.01µF = 0.0226 µF | C2 = = 0.0113 µF 0.885 0.885 1 = 4980 Hz (2.00kΩ)(2.00kΩ)(0.0226µF )(0.0113µF ) 2.00kΩ (0.0226µF )(0.0113µF ) 2 = = 0.471 2π Q= 2.00kΩ 0.0226µF + 0.0113µF 3 −−− fo = 1 2π (2kΩ 2kΩ)(82kΩ)(0.02µF )(0.02µF ) = 879 Hz | Q = The values of the resistors are unchanged. C1 = C2 = fo = € 1 2π (1kΩ)(82kΩ)(0.005µF )(0.005µF ) 82kΩ (0.02µF )(0.02µF ) = 4.53 1kΩ 0.02µF + 0.02µF 0.02µF = 0.005 µF 4 = 3520 Hz | Q = 82kΩ (0.005µF )(0.005µF ) = 4.53 1kΩ 0.005µF + 0.005µF Page 728 C 2 pF ΔvO = − 1 VI = − 0.1V = −0.4 V C2 0.5 pF vO (T ) = 0 + ΔvO = −0.4 V | vO (5T ) = 0 + 5ΔvO = −2.0 V | vO (9T ) = 0 + 9ΔvO = −3.6 V Page 732 € fo = Q= 1 C3C4 200kHz 4 pF (0.25 pF ) fC = = 10.6 kHz 2π C1C2 2π 3 pF (3 pF ) 3 pF ( 3 pF ) C3 C1C2 4 pF f 10.6 kHz = = 2 | BW = o = = 5.30 kHz C4 C1 + C2 0.25 pF 3 pF + 3 pF Q 2 ABP ( jω o ) = − R2 C 4 pF =− 3 =− = −8.00 2R1 2C4 0.5 pF 25 € ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 734 0.011000012 = 2−2 + 2−3 + 2−8 ( ) 10 ( | 0.10001000 2 = 2−1 + 2−5 = 0.3798062510 ) 10 = 0.5312510 −−− VO = VLSB 5.12V 11 2 + 2 9 + 2 7 + 2 5 + 2 3 + 21 = 3.41250 V 12 2 5.12V 5.12V = 12 = 1.25 mV | VMSB = = 2.56 V 2 2 ( ) Page 737 € VOS = VO (000) = 0.100 VFS | VLSB = 0.8VFS − 0.1VFS = 0.1 VFS 7 −−− 2R = 1 kΩ | 4 R = 2 kΩ | 8R = 4 kΩ | 16R = 8 kΩ | 32R = 16 kΩ | 64 R = 32 kΩ 128R = 64 kΩ | 256R = 128 kΩ | R = 500 Ω € Page 738 RTotal = R + 2R + 2R + ( n −1)(2R + R) = ( 3n + 2) R | RTotal = ( 3x8 + 2)(1kΩ) = 26 kΩ −−− R = 1 kΩ | 2R = 2 kΩ | 4 R = 4 kΩ | 8R = 8 kΩ | 16R = 16 kΩ | 64 R = 64 kΩ | 128R = 128 kΩ | 256R = 256 kΩ | RTotal = 511 kΩ ( ) ( ) ( 32R = 32 kΩ ) In general : RTotal = R 2 0 + 21 + ... + 2 n−1 + 2 n = 2 n+1 −1 R | RTotal = 2 8+1 −1 1kΩ = 511 kΩ € Page 739 The general case requires 2 n resistors, and the number of switches is (2 + 2 1 2 ) ( ) ( ) + ... + 2 n = 2 2 0 + 2 2 + ... + 2 n−1 = 2 2 n −1 = 2 n+1 − 2 210 = 1024 resistors | 210+1 − 2 = 2046 switches. € Page 740 (a ) In general : CTotal = R 20 + 21 + ... + 2n = 2n+1 −1 C | CTotal = 28+1 −1 1pF = 511 pF ( (b) In general : R Total € ) ( ) = 2C + 2C + ( n −1)(2C + C ) = 2R + n ( 3R) ( ) | RTotal = 2R + 8( 3kΩ) = 26 kΩ Page 741 5V 2 8 LSB VLSB = 8 = 19.53 mV | 1.2V = 61.44 LSB | The closest code is 6110 = 001111012 5V 2 € 26 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 743 2 n ≥ 10 6 | n≥ 6 log10 = 19.93 → n ≥ 20 bits log2 −−− The minimum width is 0 corresponding to the missing code 110. The maximum code width is 2.5 LSB corresponding to output code 101. DNL = 2.5 −1 = 1.5 LSB At code 110, the ADC transfer characteristic is 1 LSB off of the fitted line. ∴ INL = 1 LSB € € € € € Page 744 2n 212 1 1 conversions max TT = = = 2.048 ms | N max = max = = 488 6 fC 2x10 2.048ms second TT Page 745 n 12 1 1 conversions TT = = = 6.00 µs | N max = = = 167,000 6 fC 2x10 TT 6µs second Page 748 1 VFS = RC T VR T ∫ VR (t )dt = RC 0 VR VR 2 n 2.00V  2 8  | RC = T= =   = 0.100 ms VFS VFS f C 5.12V 1MHz  Page 749 2 n+1 217 1 1 conversions TTmax = = 6 = 0.131 s | N max = max = = 7.63 f C 10 Hz 0.131s second TT Page 750 In general, 2 n resistors and 2 n −1 comparators : ( ( ) ) 210 = 1024 resistors and 210 −1 = 1023 comparators Page 758 € fo = 1 = 15.9kHz 2π (10kΩ)(1nF ) | vo = 3(0.6V ) = 3.00 V  10kΩ  24kΩ  24kΩ 2 − 1+ −  10kΩ  12kΩ  10kΩ −−− SPICE Results :15.90 kHz, 3.33 V € 27 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 760 For vI > 0, the diode will conduct and pull the output up to vO = v I = 1.0 V. v1 = vO + vD = 1.0 + 0.6 = 1.6 V For a negative input, there is no path for current through R, so vO = 0 V. The op - amp sees a -1V input so the output will limit at the negative power supply : vO = −10 V. (Note that the output voltage will actually be determined by the reverse saturation current of the diode : vO = −I S R ≅ 0.) The diode has a 10 - V reverse bias across it, so VZ > 10 V. € Page 762 vS = +2 V : Diode D2 conducts, and D1 is off. The negative input is a virtual ground. v1 = −v D2 = −0.6 V. The current in R is 0, so vO = 0 V. vI = −2 V : Diode D1 conducts, and D2 is off. The negative input is a virtual ground. vO = − R2 68kΩ vI = − (−2V ) = +6.18 V | v1 = vO + vD1 = 6.78 V. R1 22kΩ The maximum output voltage is vOmax = 15V − 0.6V = 14.4 V. 68kΩ 14.4V = −3.09 | vI = = −4.66 V 22kΩ −3.09 When vO = 15 V , v D 2 = −15 V , so VZ = 15 V. Av = − € Page 763 20kΩ  10.2kΩ  2V vO = = 2.00 V   20kΩ  3.24kΩ  π Page 765 € VI − = − R1 1kΩ VEE = − 10V = −0.990 V R1 + R2 1kΩ + 9.1kΩ VI + = + R1 1kΩ VCC = 10V = +0.990 V R1 + R2 1kΩ + 9.1kΩ Vn = 0.990V − (−0.990V ) = 1.98 V Page 766 € € R1 6.8kΩ 1 = = R1 + R2 6.8kΩ + 6.8kΩ 2  1+ 0.5  1 T = 2(10kΩ)(0.001µF ) ln  = 21.97µs | f = = 45.5 kHz T  1− 0.5  T = 2RC ln 1+ β 1− β | β= 28 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 770  0.7  1+   R1 22kΩ 5  = 20.4 µs β= = = 0.550 | T = (11kΩ)(0.002µF ) ln R1 + R2 22kΩ + 18kΩ 1− 0.550      5V   1+ 0.55    5V   Tr = (11kΩ)(0.002µF ) ln = 13.0 µs | Tmin = 20.4µs + 13.0µs = 33.4 µs  0.7   1− 5    € 29 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 13 Page 789 (a) At the Q - point : β F = (c) Rin = IC 1.5mA = = 100 I B 15µA vbe 8mV = = 1.6 kΩ ib 5µA (b) I S = IC 1.5mA = = 1.04 fA  VBE   0.700V  exp  exp   0.025V   VT  (d ) Yes. With the given applied signal, the smallest value of vCE is min v CE = 5V − 0.5mA( 3.3kΩ) = 3.35 V which exceeds v BE = 0.708 V. (e) AvdB = 20 log −206 = 46.3 dB € Page 790 (a) No : v min DS ≅ 2.7V with vGS − VTN = 4 −1 = 3V , so the transistor has entered the triode region. (b) Choose two points on the i - v characteristics. For example, 2 2 K K 1.56mA = n ( 3.5 − VTN ) and 1.0mA = n ( 3.0 − VTN ) . 2 2 µA Solving for Kn and VTN yields 500 2 and 1 V respectively. V (c) AvdB = 20 log −4.13 = 12.3 dB Page 791 € 10kΩ 12V = 3.00 V | REQ = 10kΩ 30kΩ = 7.5 kΩ 10kΩ + 30kΩ VEQ − VBE 3.0V − 0.7V IC = β F I B = β F = 100 = 1.45 mA REQ + (β F + 1) R4 7.5kΩ + (101)(1.5kΩ) VEQ =  101  VCE = 12 − 4300IC −1500I E = 12 − 4300(1.45mA) −1500 (1.45mA) = 3.57 V  100  VB = VEQ − I B REQ = 3.00 − 1.45mA (7.5kΩ) = 2.89 V 100 € 30 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 792  101  vC (t ) = VC + vC = (5.8 −1.1sin 2000πt ) V | v E (t ) = VE + 0 = 1.45mA (1.5kΩ) = 2.20 V  100  1.1V = 0.256mA | ∠ic = 180 o | ic (t ) = −0.26sin 2000πt mA | vB (t ) = VB + vb (t ) 4.3kΩ 1.45mA VB = VEQ − I B REQ = 3.00 − (7.5kΩ) = 2.89 V | vB (t ) = (2.89 + 0.005sin sin 2000π ) V 100 −−− ic = XC = € € 1 1 = = 0.318 Ω | X C << Rin ωC 2000π (500µF ) Page 795 RB = 20kΩ 62kΩ = 15.1 kΩ | RL = 8.2kΩ 100kΩ = 7.58 kΩ Page 799 VT rd = ID + IS | rd = 0.025V 0.025V = 25.0 TΩ | rd = = 500 Ω 1 fA 50µA 0.025V 0.025V = 12.5 Ω | rd = = 8.33 mΩ 2mA 3A −−− 0.025V kT  V 0.0322V rd = = 16.7 Ω | = 8.62x10−5 (373K ) = 0.0322 V | rd = = 21.4 Ω 1.5mA q  K 1.5mA rd = € 31 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 804 g m = 40IC = 40(50µA) = 2.00 mS | rπ = ro = βo 75 = = 37.5 kΩ g m 2mS VA + VCE 60V + 5V = = 1.30 MΩ | µ f = g mro = 2mS (1.30 MΩ) = 2600 IC 50µA −−− g m = 40IC = 40(250µA) = 10.0 mS | rπ = ro = βo 50 = = 5.00 kΩ g m 10mS VA + VCE 75V + 15V = = 360 kΩ | µ f = g mro = 10mS ( 360kΩ) = 3600 IC 250µA --The slope of the output characteristics is zero, so VA = ∞ and ro = ∞. β FO = βo = βF I 1.5mA Δi 0.5mA = βF = C = = 100 | g m = C = = 62.5 mS VCE I B 15µA ΔvBE 8mV 1+ VA ΔiC 500µA = = 100 ΔiB 5µA | rπ = βo 100 = = 1.60 kΩ | g m 62.5mS rπ = Δv BE 8mV = = 1.60 kΩ ΔiB 0.5mA 100 € 32 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 814 Avt = −g m RL = −9.80mS (18kΩ) = −176 | Ten percent of the input signal is being lost by voltage division between source resistance RI and the amplifier input resistance. −−− Assume the Q - point remains constant. (a) RiB = rπ = max L ( b) R  104kΩ 12.8kΩ  125  = −162 = 12.8 kΩ | Av = −9.80mS (18kΩ)  9.80mS 1kΩ + 104kΩ 12.8kΩ   = 1.1(18kΩ) = 19.8 kΩ | RLmin = 0.9(18kΩ) = 16.2 kΩ  104kΩ 10.2kΩ   = −143 Avmin = −9.80mS (16.2kΩ)  1kΩ + 104kΩ 10.2kΩ    19.8kΩ   19.8kΩ  Avmax = Avmin   = −143  = −175  16.2kΩ   16.2kΩ  16.2kΩ    max nom 19.8kΩ Checking : Avmin = Avnom   = −159(0.9) = −143 | A v = Av   = −159(1.1) = −175  18kΩ   18kΩ    101 (c) VCE = 12V − 22kΩIC −13kΩI E = 12V − 0.275mA22kΩ + 100 13kΩ = 2.34 V 100 g m = 40(0.275mA) = 11.0 mS | RiB = rπ = = 9.09 kΩ 11.0mS  104kΩ 9.09kΩ   = −177 Av = −11.0mS (18kΩ)   1kΩ + 104kΩ 9.09kΩ  −−− β 100 AvCE ≅ −10VCC = −10(20) = −200 | g m = 40IC = 40(100µA) = 4.00 mS | RiB = rπ = o = = 25 kΩ g m 4mS VA + VCE 50V + 10V = = 600 kΩ | µ f = g mro = 4mS (600kΩ) = 2400 IC 100µA  150kΩ 25kΩ  RB RiB  = −278 Av = −g m RC ro = −4.00mS 100kΩ 600kΩ   RI + RB RiB  5kΩ + 150kΩ 25kΩ  ro = ( ) ( ) € 33 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 815 160kΩ 12V = 4.17 V | REQ = 160kΩ 300kΩ = 104 kΩ 160kΩ + 300kΩ VEQ − VBE 4.17V − 0.7V IC = β F I B = β F = 100 = 0.245 mA REQ + (β F + 1) RE 104kΩ + (101)(13kΩ) VEQ =  101  VCE = 12 − 22000IC −13000I E = 12 − 22000(0.245mA) −13000 (0.245mA) = 3.39 V  100  −−− −23  V  V  kT 1.38x10 ( 300) IC = I S exp BE 1+ CB  | VT = = = .025875 V q 1.6x10−19  VT  VA  0.245mA IS = = 422 fA  0.7  3.39 − 0.7  exp 1+  75  0.025875   Page 817 € (a ) ( ) [ ] g m = 2Kn I D (1+ λVDS ) = 2 1mA /V 2 (0.25mA) 1+ 0.02(5) = 0.742 mS 1 + VDS 50V + 5V λ ro = = = 220 kΩ | µ f = g mro = 0.742mS (220kΩ) = 163 ID 250µA ( ) [ ] g m = 2Kn I D (1+ λVDS ) = 2 1mA/V 2 (5mA) 1+ 0.02(10) = 3.46 mS 1 + VDS 50V + 10V λ ro = = = 12 kΩ | µ f = g mro = 3.46mS (12kΩ) = 41.5 ID 5mA (b) The slope of the output characteristics is zero, so λ = 0 and ro = ∞. For the positive change in vgs , g m = ΔiD ΔvGS 2.1V ≅ 3.3kΩ = 1.3 mS 0.5V Page 818 € v gs ≤ 0.2(VGS − VTN ) = 0.2 2(25mA) 2I D = 0.2 = 1.00 V | Kn 2.0mA/V 2 vbe ≤ 0.005 V Page 819 € € η= γ 2 VSB + 2φ F = 0.75 2 0 + 0.6 = 0.48 | η= 0.75 2 3 + 0.6 34 = 0.20 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 821 gm = 2 I DSS I D (1+ λVDS ) VP =2 [ ] = 3.32 mS 5mA(2mA) 1+ 0.02(5) −2 1 + VDS 50V + 5V ro = λ = = 27.5 kΩ | µ f = g mro = 3.32mS (27.5kΩ) = 91.3 ID 2mA   ID  2mA   = −2V 1−  = −0.735 V VGS = VP 1− I DSS  5mA    v gs ≤ 0.2(VGS − VP ) = 0.2(−0.735 + 2) = 0.253 V Page 829 € 1.5 MΩ 12V = 4.87 V | REQ = 1.5 MΩ 2.2 MΩ = 892 kΩ 1.5 MΩ + 2.2 MΩ Neglect λ in hand calculations of the Q - point.  5x10−4  2 4.87 = VGS + 12000I D | 4.87 = VGS + 12000 (VGS −1)  2  VEQ = 3VGS2 − 5VGS −1.87 = 0 → VGS = 1.981 V | I D = 241 µA VDS = 12 − 22000I D −12000I D = 3.81 V | Q - point : (241 µA, 3.81 V ) −−− The small - signal model appears in Fig. 13.27(c). −−− VGS − VTN ≅ 2(241µA) 2x10−3 = 0.491 V | AvCS ≅ − 12V = −24.4 0.491V | M= Kn2 2x10−3 = =4 Kn1 5x10−4 Page 831 € rπ = β oVT 100(0.025V ) = = 3.45 kΩ | RinCE = RB rπ = 104kΩ 3.45kΩ = 3.34 kΩ IC 0.725mA Page 832 € RinCS = 680kΩ 1.0 MΩ = 405 kΩ | VEQnew = VEQold = 1.5 MΩ VDD = 0.405VDD 1.5 MkΩ + 2.2 MΩ 680kΩ VDD = 0.405VDD 680kΩ + 1MΩ | No change. The gate voltages are the same. € 35 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 837 From Ex. 13.6, µ f = 230 and Av = −20.3. Av << µ f −−−  VGS = VP 1−  ID I DSS   0.25mA   = −1V 1−  = −0.500 V 1mA    v gs ≤ 0.2(VGS − VP ) = 0.2(−0.5 + 1) = 0.100 V | v o ≤ 20.3(0.1) = 2.03 V −−− SPICE Results : λ = 0 : Q - point = (250 µA, 4.75 V ) | λ = 0.02 V −1 : Q - point = (257 µA, 4.54 V ) Page 840 €  66  IC = 245 µA | VCE = 3.39 V | I E = 245µA  = 249 µA  65  245µA PD = ICVCE + I BVBE = 245µA(3.39V ) + (0.7V ) = 0.833 mW 65 V − VB VCC − (VBE + I E RE ) 12 − 0.7 − 0.249mA(13kΩ) PS = VCC ( IC + I2 ) | I2 = CC = = = 26.9 µA R2 R2 300kΩ PS = 12V (245µA + 26.9µA) = 3.26 mW −−− PD = I DVDS = 241µA(3.81V ) = 0.918 mW | PS = VDD ( I D + I2 ) I2 = € VDD 12V = = 3.24 µA | PS = 12V (241µA + 3.24µA) = 2.93 mW R1 + R2 1.5MΩ + 2.2 MΩ Page 842 (a) VM ≤ min IC RC , (VCE − VBE ) = min 245µA(22kΩ), (3.39 − 0.7)V = 2.69 V [ ] [ ] VM is limited by the value of VCE . ( b) V M [ ] [ ] ≤ min I D RD , (VDS − VDSSAT ) = min 241µA(22kΩ), ( 3.81− 0.982)V = 2.83 V Limited by the value of VDS . € 36 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 14 Page 860 160kΩ 12V = 4.17 V | REQ = 160kΩ 300kΩ = 104 kΩ 160kΩ + 300kΩ VEQ − VBE 4.17V − 0.7V IC = β F I B = β F = 100 = 0.245 mA REQ + (β F + 1) RE 104kΩ + (101)(13kΩ) VEQ =  101  VCE = 12 − 22000IC −13000I E = 12 − 22000(0.245mA) −13000 (0.245mA) = 3.39 V  100  g m = 40IC = 40(0.245mA) = 9.80 mS | rπ = ro = βo 100 = = 10.2 kΩ g m 9.80mS VA + VCE 53.4V = = 218 kΩ | µ f = g mro = 2140 IC 0.245mA −−− 1.5 MΩ 12V = 4.87 V | REQ = 1.5 MΩ 2.2 MΩ = 892 kΩ 1.5 MΩ + 2.2 MΩ Neglect λ in hand calculations of the Q - point.  5x10−4  2 4.87 = VGS + 12000I D | 4.87 = VGS + 12000 (VGS −1)  2  VEQ = 3VGS2 − 5VGS −1.87 = 0 → VGS = 1.981 V | I D = 241 µA VDS = 12 − 22000I D −12000I D = 3.81 V | Q - point : (241 µA, 3.81 V ) ( )( ) g m = 2Kn I D = 2 5x10−4 2.41x10−4 = 0.491 mS | ro = λ−1 + VCE 53.8V = = 223 kΩ IC 0.241mA µ f = g mro = 110 € Page 861 RB = 160kΩ 300kΩ = 104 kΩ | RE = 3.00 kΩ | RL = 22kΩ 100kΩ = 18.0 kΩ RG = 1.5 MΩ 2.2 MΩ = 892 kΩ | RS = 2.00 kΩ | RL = 22kΩ 100kΩ = 18.0 kΩ −−− RB = 160kΩ 300kΩ = 104 kΩ | RL = 13kΩ 100kΩ = 11.5 kΩ RG = 1.5 MΩ 2.2 MΩ = 892 kΩ | RL = 12kΩ 100kΩ = 10.7 kΩ € 37 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 863 RI = 2 kΩ | R6 = 13 kΩ | RL = 22kΩ 100kΩ = 18.0 kΩ RI = 2 kΩ | R6 = 12 kΩ | RL = 22kΩ 100kΩ = 18.0 kΩ € 38 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 875 V −V 1 (a) IC ≅ REQ + RBE or IC ∝ R + R E 4 E 4 For large gm RE , AvtCE = − | IC = 0.245mA 13kΩ RE + R4 RC R3 g m RL R ≅− L =− 1+ g m RE RE RE For AvtCE max make RC and R3 large and RE small. RL = 1.1(22kΩ) 1.1(100kΩ) = 19.8 kΩ RE = 0.9( 3kΩ) = 2.7 kΩ | IC = 0.245mA 13kΩ = 0.251 mA | g m = 40(0.251 mA) = 10.0 mS 12.7kΩ βo 100 = = 10.0 kΩ | RiB = 10.0kΩ + 101(2.7kΩ) = 283 kΩ g m 10.0mS 10.0mS (19.8kΩ)  104kΩ 283kΩ    = −6.98 AvCE max = − 1+ 10.0mS (2.7kΩ)  1kΩ + 104kΩ 283kΩ  rπ = For AvtCE min make RC and R3 small and RE large. RL = 0.9(22kΩ) 0.9(100kΩ) = 16.2 kΩ RE = 1.1( 3kΩ) = 3.3 kΩ | IC = 0.245mA 13kΩ = 0.239 mA | g m = 40(0.239 mA) = 9.56 mS 13.3kΩ βo 100 = = 10.5 kΩ | RiB = 10.5kΩ + 101( 3.3kΩ) = 344 kΩ g m 9.56mS 9.56mS (16.2kΩ)  104kΩ 344kΩ    = −4.70 AvCE min = − 1+ 9.56mS ( 3.3kΩ)  1kΩ + 104kΩ 344kΩ  rπ = (b) Assume the collector current does not change. βo 125 = = 12.8 kΩ | RiB = 12.8kΩ + 126( 3.0kΩ) = 391 kΩ g m 9.8mS 9.80mS (18kΩ)  104kΩ 391kΩ    = −5.73 The gain is essentially unchanged. AvCE = − 1+ 9.80mS ( 3kΩ)  1kΩ + 104kΩ 391kΩ    101 (c) VCE = VCC − IC RC − I E ( RE + R4 ) = 12V − 0.275mA22kΩ + 100 13kΩ = 2.34 V 2.34 V > 0.7 V Therefore the transistor is still in the active region. β 100 g m = 40(0.275mA) = 11.0 mS | rπ = o = = 9.09 kΩ | RiB = 9.09kΩ + 101( 3.0kΩ) = 312 kΩ g m 11mS 11.0mS (18kΩ)  104kΩ 312kΩ  CE   = −5.75 The gain is essentially unchanged. Av = − 1+ 11.0mS ( 3kΩ)  1kΩ + 104kΩ 312kΩ  rπ = Continued on the next page € 39 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 875 cont.   100(2kΩ)  = 5.17 MΩ | µ R = 3140(2kΩ) = 6.28 MΩ RiC = 320kΩ 1+ f E   1kΩ 104kΩ + 10.2kΩ + 2kΩ   ( RiC < µ f RE ) | Rout = 5.17 MΩ 22kΩ = 21.9 kΩ | Rout << µ f RE −−−    β R  β o RE lim RiC = lim ro 1+ = ro1+ o E  = (β o + 1)ro  R E →∞ RE  R E →∞  Rth + rπ + RE   € Page 877 RiB = 10.2kΩ + 101(1kΩ) = 111 kΩ 9.80mS (18kΩ)  104kΩ 111kΩ    = −16.0 Av = − 1+ 9.80mS (1kΩ)  1kΩ + 104kΩ 111kΩ  | R4 = 13kΩ −1kΩ = 12 kΩ. −−− −23  V  V  kT 1.38x10 ( 300) BE CB IC = I S exp = = .025875 V 1+  | VT = q 1.60x10−19  VT  VA  IS = 0.245mA = 425 fA  0.7  3.39 − 0.7  exp 1+  100   0.025875  −−− AvCE ≅ −10VCC = −10(20) = −200 | g m = 40IC = 40(100µA) = 4.00 mS | RiB = rπ = β o 100 = = 25 kΩ g m 4mS VA + VCE 50V + 10V = = 600 kΩ | µ f = g mro = 4mS (600kΩ) = 2400 IC 100µA  150kΩ 25kΩ  RB RiB  = −278 AvCE = −g m RC ro = −4.00mS 100kΩ 600kΩ   RI + RB RiB 5kΩ + 150kΩ 25kΩ   ro = ( ) ( ) € 40 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 884 1.5 MΩ 12V = 4.87 V | REQ = 1.5 MΩ 2.2 MΩ = 892 kΩ 1.5 MΩ + 2.2 MΩ Neglect λ in hand calculations of the Q - point.  5x10−4  2 4.87 = VGS + 12000I D | 4.87 = VGS + 12000 (VGS −1)  2  VEQ = 3VGS2 − 5VGS −1.87 = 0 → VGS = 1.981 V | I D = 241 µA VDS = 12 − 22000I D −12000I D = 3.81 V | Q - point : (241 µA, 3.81 V ) −−− CS AvdB = 20 log −4.50 = −13.1 dB −−− RiB = 10.2kΩ + 101(1kΩ) = 111kΩ CE v A 9.80mS (18kΩ)  104kΩ 111kΩ    = −16.0 | R4 = 13kΩ −1kΩ = 12 kΩ =− 1+ 9.80mS (1kΩ)  1kΩ + 104kΩ 111kΩ  AvCS = − (iii ) € 0.503mS (18kΩ)  892kΩ    = −6.02 | R4 = 12kΩ −1kΩ = 11 kΩ 1+ 0.503mS (1kΩ)  1kΩ + 892kΩ  RiB = 10.2kΩ + 101(13kΩ) = 1.32 MΩ AvCE = − 9.80mS (18kΩ)  104kΩ 1.32 MΩ    = −1.36 | AvCE ≅ − RL = − 18kΩ = −1.38 RE + R4 13kΩ 1+ 9.80mS (13kΩ)  1kΩ + 104kΩ 1.32 MΩ  AvCS = − 0.503mS (18kΩ)  892kΩ  RL 18kΩ CS =− = −1.50   = −1.29 | Av ≅ − RS + R4 12kΩ 1+ 0.503mS (12kΩ)  1kΩ + 892kΩ  Page 885  1.381x10−23 V  IC 245µA VT =  = = 0.430 fA (273K + 27K ) = 25.861 mV | I S = −19  VBE   0.700V  1.602x10 K  exp  exp   0.025861V   VT  −−− 18kΩ g m RL = -9.80mS(18kΩ) = −176 | AvCE ≅ − = −6.00 | 5.72 < 6.00 3kΩ 18kΩ g m RL = -0.503mS(18kΩ) = −9.05 | AvCS ≅ − = −9.00 | 4.50 < 9.00 2kΩ € 41 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 889 2.5V 1+ 10mS (11.5kΩ) = 1.16 MΩ 0.25mA [ RB = 160kΩ 300kΩ = 104kΩ | RiB ≅ rπ (1+ g m RL ) = vi ≤ 0.005V (1+ g m RL ) RI + RB RiB RB RiB vi ≤ 0.2(VGS − VTN )(1+ g m RL ) € [ = 0.005V 1+ 10mS (11.5kΩ) ] + 95.4kΩ = 0.592 V ] 2kΩ95.4kΩ RI + RG 2kΩ + 892kΩ = 0.2(1V ) 1+ 0.5mS (10.7kΩ) = 1.27 V RG 892kΩ [ Page 894 2kΩ + 892kΩ Avt = 0.971 = 0.973 | 892kΩ ] (0.491ms) R 1+ (0.491ms ) R L = 0.973 → RL = 73.4kΩ L R6 100kΩ = 73.4kΩ → R6 = 276 kΩ | Note, however, that the 12 kΩ resistor can't simply be replaced with a 276 kΩ resistor because of Q - point problems. −−− RiB = 10.2kΩ + 101(13kΩ) = 1.32 MΩ | RinCC = 104kΩ 1.32 MΩ = 96.4kΩ AvCE = − 9.80mS (13kΩ)  96.4kΩ    = +0.972 1+ 9.80mS (13kΩ)  2kΩ + 96.4kΩ  AvCS = − 0.491mS (12kΩ)  892kΩ    = +0.853 1+ 0.491mS (12kΩ)  2kΩ + 892kΩ  −−− BJT : g m RL = 9.80mS (11.5kΩ) = 113 | FET : g m RL = 0.491mS (10.7kΩ) = 5.25 Page 896 € BJT : v i ≤ 0.005V (1+ g m RI )  2kΩ + 13kΩ  RI + R6 = 0.005V 1+ 9.8mS (2kΩ)   = 119 mV R6  13kΩ  [ ] [ ] Neglecting R6 , v i ≤ 0.005V (1+ g m RI ) = 0.005V 1+ 9.8mS (2kΩ) = 103 mV FET : v i ≤ 0.2(VGS − VTN )(1+ g m RI ) RI + R6 2kΩ + 12kΩ = 0.2(0.982) 1+ 0.491mS (2kΩ) = 454 mV R6 12kΩ [ ] [ ] Neglecting R6 , v i ≤ 0.2(VGS − VTN )(1+ g m RI ) = 0.2(0.982) 1+ 0.491mS (2kΩ) = 389 mV € 42 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 898   100(1.73kΩ)  β R   = 3.40 MΩ RiC = ro 1+ o th  = 219kΩ 1+  Rth + rπ   1.73kΩ + 10.2kΩ [ ] Or more approximately, RiC = ro [1+ g m Rth ] = 219kΩ 1+ 9.8mS (1.73kΩ) = 3.93 MΩ [ ] RiD = ro [1+ g m Rth ] = 223kΩ 1+ 0.491(1.71kΩ) = 410 kΩ Page 902 € AvCB AvCB  1 R6  R6  gm  1 1 R6 + R6 + R6 gm gm = g m RL = g m RL = g m RL  1 R6 R6 (1+ g m RI ) + RI g m RI + R6   1  gm  R6 + RI + gm 1 R6 + gm R6 1 g m RL  R6  = g m RL =   g R R 1+ g m Rth  R6 + RI  R6 + RI 1+ m I 6 R6 + RI −−− The voltage gains are proportional to the load resistance  22kΩ   22kΩ  CG AvCE = +8.48   = +10.4 | Av = +4.12   = +5.02  18kΩ   18kΩ  −−− R RL 18kΩ CB : AvCB ≤ g m RL = 176 | AvCB ≅ L = = = 10.4 | Rth RI R6 1.73kΩ CG : AvCG ≤ g m RL = 8.84 | AvCB ≅ RL RL 18kΩ = = = 10.5 Rth RI R6 1.71kΩ 8.48 < 10.4 << 176 | 4.11 < 8.84 < 10.5 Page 909 € AvCS = 1 1+ η (W L) (W L) 1 2 26 | 10 20 = 1 1+ 0.2 (W L) 1 4 = 2290 1 € 43 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 911 η = 0 | I D 2 = I D1 | Both transistors are in the active region since VDS = VGS . 2 2 10−4  2  10−4  8  Neglecting λ :  (5 − VO −1) =  (VO −1) → VO = 2.00 V 2  1 2  1 2 2 10−4  2  10−4  8  Keeping λ :  (5 − VO −1) 1+ 0.02(5 − VO ) =  (VO −1) (1+ 0.02VO ) → 2  1 2 1 [ ] VO = 2.0064 V , I D = 421.39 µA → Q − point : (2.01 V , 421 µA) −−− I D2 = I D1 | Both transistors are in the active region since VDS = VGS .  20   50  A A Kn = 10−4   = 2x10−3 2 | K p = 4 x10−5   = 2x10−3 2 | The transistors are symmetrical. V V 1 1 2 V 3.3V 10−4  20  ∴ VO = DD = = 1.65 V | I D =  (1.65 − 0.7) 1+ 0.02(1.65) = 932 µA 2 2 2 1 [ ] Q − point : (1.65 V , 932 µA) € Page 914 Since we need high gain, the emitter should be bypassed, and RinCE = RB rπ = 250kΩ. If we choose RB ≅ rπ , IC = βo 100 ≅ = 5 µA 40rπ 40(500kΩ) −−− RinCG ≅ 1 gm | IC ≅ 1 = 12.5 µA 40(2kΩ) € 44 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 918 Common − Emitter : C1 >> 1 = 8.07nF | Choose C1 = 82 nF = 0.082 µF 2π (250Hz)(1kΩ + 77.9kΩ) C2 >> 1 = 6.13nF | Choose C2 = 68 nF = 0.068 µF 2π (250Hz)(21.9kΩ + 82kΩ) C3 >> 1 = 0.269µF | Choose C3 = 2.7 µF   1  2π (250Hz)10kΩ  3kΩ +  9.80mS    Common − Source : C1 >> 1 = 713 pF | Choose C1 = 8200 pF 2π (250Hz)(1kΩ + 892kΩ) C2 >> 1 = 6.15nF | Choose C2 = 68 nF = 0.068 µF 2π (250Hz)(21.5kΩ + 82kΩ) C3 >> 1 = 0.221µF | Choose C3 = 2.2 µF    1 2π (250Hz)10kΩ  2kΩ +  0.491mS    Page 921 € Common − Collector : 1 C1 >> = 6.60nF | Choose C1 = 68 nF = 0.068 µF 2π (250Hz)(1kΩ + 95.5kΩ) C2 >> 1 = 7.75nF | Choose C2 = 82 nF = 0.082 µF 2π (250Hz)(120Ω + 82kΩ) Common − Drain : C1 >> 1 = 713 pF | Choose C1 = 8200 pF 2π (250Hz)(1kΩ + 892kΩ) C2 >> 1 = 7.60nF | Choose C2 = 82 nF = 0.082 µF 2π (250Hz)(1.74kΩ + 82kΩ) € 45 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 924 Common − Base : C1 >> 1 = 0.579µF | Choose C1 = 6.8 µF 2π (250Hz)(1kΩ + 0.1kΩ) C2 >> 1 = 6.13nF | Choose C2 = 0.068 µF 2π (250Hz)(21.9kΩ + 82kΩ) C3 >> 1   2π (250Hz)160kΩ 300kΩ 10.2kΩ + 101 13kΩ 1kΩ    [ ( )] = 12.2nF | Choose C3 = 0.12 µF Common − Gate : C1 >> 1 = 0.232µF | Choose C1 = 2.2 µF 2π (250Hz)(1kΩ + 1.74kΩ) C2 >> 1 = 6.19nF | Choose C2 = 0.068 µF 2π (250Hz)(20.9kΩ + 82kΩ) C3 >> 1 ( ) 2π (250Hz) 1.5 MΩ 2.2 MΩ = 714 pF | Choose C3 = 8200 pF Page 925 € (a ) Common − Source : C3 = 1 = 55.3nF | Choose C3 = 0.056 µF    1 2π (1000Hz)10kΩ  2kΩ +  0.491mS    (b) Common − Collector : C2 >> 1 = 795 pF | Choose C2 = 820 pF 2π (2000Hz)(120Ω + 100kΩ) (c) Common − Gate : C1 >> 1 = 42.6nF | Choose C1 = 0.042 µF 2π (1000Hz)(2kΩ + 1.74kΩ) € 46 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 929 2 0.020 VGS −1.5) → VGS = 2.203 V | I D = 4.94 mA ( 2 = 5 − (−VGS ) = 7.20 V | Q - point : (4.94 mA, 7.20 V) | Rin = RG = 22 MΩ 20V = VGS + 3600I D | 20 = VGS + 3600 VDS AvCD = g m RL 1+ g m RL | gm = 2( 4.94mA) (2.20 −1.50)V = 14.2 mS | RL = 3600Ω 3000Ω = 1630 Ω | AvCD = 0.959 −−− CD Rout = 3.6kΩ 1 1 = 3.6kΩ = 69.1 Ω | v gs ≤ 0.2(2.20 −1.50) 1+ 0.0142(1630) = 3.38 V gm 0.0142 [ ] −−− 1 1 + VDS + 5 + 2.21 ro = λ = 0.015 = 14.8 kΩ | RL = 3600Ω 3000Ω 14.8kΩ = 1470 Ω | AvCD = 0.954 ID 0.005 −−− W Kn 2x10−2 400 = = = L Kn′ 5x10−5 1 € Page 930 g R A= m S 1+ g m RS CD Rout = 3.6kΩ | gm = 2( 4.94mA) (2.20 −1.50)V = 14.2 mS | RS = 3600 Ω | AvCD = 0.981 | Rin = RG = 22 MΩ 1 1 3000Ω = 3.6kΩ = 69.1 Ω | AvCD = A = 0.959 gm 0.0142 69.1Ω + 3000Ω € 47 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 933 Reverse the direction of the arrow on the emitter of the transistor as well as the values of VEE and VCC . −−− RinCG = RE 1 1 75.1Ω = 13kΩ = 75.1 Ω | AvCB = (13.2mS )(7.58kΩ) = 50.1 gm 75Ω + 75.1Ω 40(331µA) −−− For vCB ≥ 0, we require v C ≥ 0. VC = 5 − IC RC = 2.29 V ∴ v c ≤ 2.29 V vo ≤ 5mV ( g m RL ) = 5mV (13.2mS )( 7580Ω) = 0.500 V −−− [ ] RE = 75Ω 1+ 40(7.5 − 0.7) = 20.5 kΩ (a standard 1% value) | IC ≅ 6.8V = 332 µA 20.5kΩ 75 → RL = 7.53kΩ → RC = 8.14 kΩ → 8.06 kΩ (a standard 1% value) 75 + 75 = 0.7 + 7.5 − IC RC = 5.52 V 50 = 40( 332µA) RL VEC Page 934 € 5% tolerances ICmax ≅ VEEmax − 0.7V 5(1.05) − 0.7V = = 368µA REmin 13kΩ(0.95) min VCmin = VCC − ICmax RCmax = 5V (0.95) − 368µA(8.2kΩ)(1.05) = 1.58 V | 1.58 ≥ 0, so active region is ok. 10% tolerances ICmax ≅ VEEmax − 0.7V 5(1.1) − 0.7V = = 410µA REmin 13kΩ(0.9) min VCmin = VCC − ICmax RCmax = 5V (0.90) − 410µA(8.2kΩ)(1.1) = 0.802 V | 0.802 ≥ 0, so active region is ok. −−− RinCB 75 vth = v i g R = vi (13.2mS )(8200Ω) = 54.1vi CB m C 75Ω + 75 75Ω + Rin AvCG = CB | Rth = Rout = 8.2 kΩ v o vth 100kΩ 100kΩ = = 54.1 = 50.0 v i vi Rth + 100kΩ 8.2kΩ + 100kΩ € 48 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 939 ro ≅ ro = 1 1 = = 333 kΩ λI D 0.015 2x10−4 ( ) or more exactly VDS = 25 −10 5 I D − 9.1x10 3 I D = 25 −1.09x10 5 (0.2mA) = 3.18 V 1 1 + VDS + 3.18 λ 0.015 ro = = = 349 kΩ | RL = 100kΩ 100kΩ 349kΩ = 43.7 kΩ ID 2x10−4 AvCS = −( g m RL )  75Ω  2(0.2mA) Rin =− 43.7kΩ) (  = −43.7 RI + Rin 0.2V  75Ω + 75Ω  −−− 2 0.01 0.25) = 0.3125 mA | VGS − VTN = 0.25 V | VGS = 0.25 − 2 = −1.75 V ( 2 −V 1.75V A 50(0.25V ) RS = GS = = 5.60kΩ → 5.6 kΩ | RL = 2 v = = 40 kΩ | RD 100kΩ = 40 kΩ ID 0.3125mA g m 0.3125mA ID = RD = 66.7kΩ → 68 kΩ | C1 remains unchanged. C2 >> C3 >> 1 = 1.90 pF → Choose C2 = 20 pF 10 π (68kΩ + 100kΩ) 6 1  1  10 π  5.6kΩ  2.5mS   = 0.853nF → Choose C3 = 8200 pF 6 −−− vth = v i RinCG 75Ω g R = vi (2mS )(100kΩ) = 100vi CG m D 75Ω + 75Ω 75Ω + Rin AvCG = v o vth 100kΩ 100kΩ = = 100 = 50.0 v i vi Rth + 100kΩ 100kΩ + 100kΩ CG | Rth = Rout = 100 kΩ € 49 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 941 2 2 Kn 0.01 VGS − VTN ) | VGS = −RS1 I D | I D = −200I D + 2) → I D = 5.00 mA ( ( 2 2 = 15 − 5mA(820Ω) = 10.9 V M1 : I D = VDS g m = 2Kn I D = 2(0.01)(0.005) = 10.0 mS | ro = 1+ λVDS 1+ 0.02(10.9) = = 12.2 kΩ λI D 0.02(5mA) 22kΩ (15V ) = 3.30 V | REQ = 22kΩ 78kΩ = 17.2 kΩ 22kΩ + 78kΩ   3.30 − 0.7 151 IC = 150 = 1.52 mA | VCE = 15 −1.52mA 4.7kΩ + 1.6kΩ = 5.41 V 150 17.2kΩ + 151(1.6kΩ)   Q2 : VEQ = g m = 40(1.52mA) = 60.8 mS | rπ = 150 80 + 5.41 = 2.47 kΩ | ro = = 56.2 kΩ 60.8mS 1.52mA 120kΩ (15V ) = 8.53 V | REQ = 120kΩ 91kΩ = 51.8 kΩ 120kΩ + 91kΩ  81  8.53 − 0.7 IC = 80 = 1.96 mA | VCE = 15 −1.96mA 3.3kΩ = 8.45 V 51.8kΩ + 81( 3.3kΩ)  80  Q3 : VEQ = g m = 40(1.96mA) = 78.4 mS | rπ = 80 60 + 8.45 = 1.02 kΩ | ro = = 34.9 kΩ 78.4mS 1.96mA −−− A typical op - amp gain is at least 10,000 which exceeds the amplification factor of a single transistor. € Page 943 RL1 = 478Ω 12.2kΩ = 460 Ω | RL2 = 3.53kΩ 54.2kΩ = 3.31 kΩ | RL3 = 232Ω 34.4kΩ = 230 Ω  79.6mS (230Ω)   1MΩ  Av = −10mS ( 460Ω)(−62.8mS )( 3.31kΩ)  = 898 1+ 79.6mS (230Ω) 10kΩ + 1MΩ  20 log(898) = 59.1 dB −−−  VDD  15 Av ≅ − (−10VCC )(1) = − (−10)(15)(1) = 2250 1  VGS − VTN  −−− Av = −10mS (2.39kΩ)(−62.8mS )(19.8kΩ)(0.95)(0.99) = 28000 € 50 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 948  1 3990  Rout = 3300  +  = 55.9 Ω  0.0796S 90.1  −−− Note that the answers are obtained directly from SPICE. −−− ( ) Av1 = −g m RL1 = − 2(0.01)(0.001) 3kΩ 17.2kΩ 2.39kΩ = 5.52 Av = −5.52(−222)( 3.31kΩ)(0.95)(0.99) = 1150 € 51 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 15 Page 972 60  15 − 0.7   = 93.8 µA | VCE = 15 − 93.8µA( 75kΩ) − (−0.7V ) = 8.67 V IC = α F I E =  61 2 ( 75kΩ)  −−− IC = α F I E =   60  15 − VBE  IC   and VBE = 0.025V ln   → IC = 94.7 µA, VBE = 0.649 V -15 61 2 ( 75kΩ)   0.5x10 A  Page 974 € v1 + v 2 1.01+ 0.99 = = 1.00 V 2 2 v +v 4.995 + 5.005 vid = v1 − v2 = 4.995 − 5.005 = −0.010 V | v ic = 1 2 = = 5.00 V 2 2 vod = Add v id + Acd v ic | v oc = Adcv id + Accvic vid = v1 − v2 = 1.01− 0.990 = 0.020 V | v ic = 2.20  0.02   = [ Add Acd ]   0  −0.01 1.002  0.02   = [ Adc Acc ]  5.001 −0.01 € 1.00  → [ Add Acd ] = [100 0.20] 5.00 1.00  → [ Adc Acc ] = [0.100 1.00] 5.00 Page 978 Differential output : Adm = Add = −20VCC = −300 | Acm = 0 Single - ended output : Adm = Add = +10VCC = 150 2 | CMRR = ∞ | CMRR = 20VEE = 300 | Acm = − 150 = −0.5 300 Page 982 €  100  R  15 − 0.7  1−   C  101  2RC  15   VIC = 15V = 5.30 V   100  RC  1+     101  2RC    Page 983 € € I DC = I SS − VO 15V = 100µA − = 80 µA RSS 750kΩ 52 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 985 I I D = SS = 100 µA | VDS = 12 − I D RD + VGS = 12 −100µA(62kΩ) + VGS = 5.8V + VGS 2 2I D VGS = VTN + = VTN + 0.2V | VTN = 1+ 0.75 VSB + 0.6 − 0.6 | VSB = −VGS − (−12V ) Kn ( VSB = 11.8 − VTN ( ) ) | VTN = 1+ 0.75 12.4 − VTN − 0.6 → VTN = 2.75V | VDS = 8.75 V Q − point : (100 µA, 8.75 V ) Page 988 € Rod = 2ro ≅ 2 VA 60V =2 = 3.20 MΩ | Roc ≅ 2µ f REE = 2( 40)(60)(1MΩ) = 4.80 GΩ IC 37.5µA idm = g mvdm = 40( 37.5µA)vdm = 1.5x10−3 vdm | icm ≅ v cm v = cm = 5.00x10−7 v cm 2REE 2 MΩ Page 993 € IC1 = IC 2 = 100  150µA  15V = 750 µA | VCE 3 = 15 − 0 = 15.0 V   = 74.3 µA | IC 3 = 101  2  20kΩ VCE1 = 15 − 74.3µA(10kΩ) − (−0.7) = 15.0 V | VCE 2 = 15 − (74.3µA − 7.5µA)(10kΩ) − (−0.7) = 15.0 V VEB 3 = ( 74.3µA − 7.5µA)(10kΩ) = 0.668 V | I S 3 = 750µA = 1.87x10−15 A  0.668V  exp   0.025  Page 996 € max Adm = 560 (15) = 8400 | IC1 ≤ 50(1µA) = 50 µA | Adm = IC1 ≤ 50(1µA) = 50 µA | Adm = 8400 = 2210 28  500µA  1+   100  50µA  8400 = 290 28  5mA  1+   100  50µA  −−− Rin = 2rπ = 2 50 15V = 50 kΩ | Rout ≅ = 30 kΩ 0.5mA 40(50µA) Rin = 2rπ = 2 50 15V = 50 kΩ | Rout ≅ = 3.0 kΩ 5mA 40(50µA) −−− max Adm = 560 (1.5) = 840 53 € ©R. C. Jaeger and T. N. Blalock 09/25/10 54 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 997 CMRR ≅ g m2 R1 = 40 (50µA)( 750kΩ) = 1500 | CMRRdB = 20 log(1500) = 63.5 dB € Page 998  0.7r  g  Rr  40  I R r  560VA 3 π3 Adm = m2  C π 3 (g m3ro3 ) =  C 2 C π 3 ( 40IC 3ro3 ) ≅ 800 (VA3 ) = R 2  RC + rπ 3  2  RC + rπ 3   RC + rπ 3  1+ C rπ 3 Adm = 560VA 3 560VA 3 560VA 3 560VA 3 = = =   40IC 3 RC 40(0.7)  IC 3  40IC 2 RC IC 3 28  IC 3  1+ 1+ 1+   1+     β o3 β o3  IC 2  β o3  IC 2  β o3  IC 2  −−− max Adm = 560 ( 75) = 42000 | IC1 ≤ 50(1µA) = 50 µA Adm = 42000 = 11000 28  500µA  1+   100  50µA  | Adm = 42000 = 1450 28  5mA  1+   100  50µA  −−− Rin = 2rπ = 2 50 75V + 15V = 50 kΩ | Rout ≅ ro3 = = 180 kΩ 0.5mA 40(50µA) Rin = 2rπ = 2 50 90V = 50 kΩ | Rout ≅ = 18.0 kΩ 5mA 40(50µA) € 55 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1002 Avt1 = −3.50 | Avt 2 = −22mS 150kΩ 162kΩ 203kΩ = −1238 ( Avt 3 = ( ) 0.198S 2kΩ 18kΩ ( ) 1+ 0.198S 2kΩ 18kΩ Rin = 2rπ = 2 ) = 0.9971 | Adm = −3.50(−1238)(0.9971) = 4320 ro3 R2 162kΩ 150kΩ 100 1 1 = 101 kΩ | Rout ≅ + = + = 776 Ω g m4 β o4 + 1 40( 4.95mA) 101 40( 49.5µA) P ≅ ( I1 + I 2 + I 3 )(VCC + VEE ) = (100 + 500 + 5000)µA(30V ) = 168 mW −−− 150  5mA 0.7V IC = 50µA = 533 µA | RC = = 15.2 kΩ  = 49.7 µA | IC 3 = 500µA +  151 533  151   49.7 − µA 150   rπ 3 = 150 = 7.04 kΩ | Avt 2 = −20( 49.7µA) 15.2kΩ 7.04kΩ = −4.68 40(533µA) IC 4 = 150 150 75 + 14.3 5mA = 4.97 mA | rπ 4 = = 755 Ω | ro3 = = 168 kΩ 151 533µA 40( 4.97mA) ( [ ) ] Avt 2 = −40(533µA) 168kΩ 755 + 151(2kΩ) = −2304 g m4 = 40(4.97mA) = 0.199 S | Avt 3 = 0.199S (2kΩ) 1+ 0.199S (2kΩ) = 0.998 Adm = −4.78(−2304 )(0.998) = 11000 Rid = 2rπ 1 = 2 ro3 R2 150 1 1 168kΩ = 151 kΩ | Rout ≅ + = + = 1.12 kΩ g m4 β o4 + 1 40(4.95mA) 151 40( 49.7µA) CMRR is set by the input stage and doesn't change since the bias current is the same. −−− ro3 = 2 50 + 14.3 = 117 kΩ | Avt 2 = −22mS 117kΩ 203kΩ = −1630 | Adm = −3.50(−1630)(0.998) = 5700 550µA ( ) ro3 R2 100 1 1 117kΩ = 101 kΩ | Rout ≅ + = + = 1.16 kΩ g m4 β o4 + 1 40(4.95mA) 101 40( 49.5µA) CMRR and input resistance are set by the input stage and don't change. −−− T 6920 R 1.62kΩ = = 0.99986 | TOC = T | TSC = 0 | Rout = o = = 0.234 Ω 1+ T 6921 1+ T 1+ 6920 Rin ≅ Rid (1+ TSC ) = 101kΩ(6921) = Rid (1+ T ) = 699 MΩ (Assuming TOC << 1) Av = € 56 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1004 2(500µA) VGS 3 = 1+ Avt1 = − = 1.63 V | RD = 2.5mA 1.63V = 16.3 kΩ 100µA   1 1  = −316 2(0.005)(100µA) (16.3kΩ) = −8.16 | Avt 2 = −g m3ro3 = − 2(0.0025)(0.0005)  2  0.01(0.5mA)  g m4 = 2(0.005mA)(0.005mA) = 7.07 mS | Avt 3 = 7.07mS (2kΩ) 1+ 7.07mS (2kΩ) Adm = −8.16(−316)(0.934 ) = 2410 | Rid = ∞ | Ro = = 0.934 1 1 = = 141 Ω g m4 7.07mS CMRR = g m1 R1 = 1.00mS ( 375kΩ) = 375 or 51.5 dB −−− P ≅ ( I1 + I 2 + I 3 )(VDD + VSS ) = (5.7mA)(24V ) = 137 mW Page 1005 € € Add1 = − Kn′ KP′ (W L) (W L) | 10 = 2.5 2 L2 (W L) 4 2 → (W L) 2 = 160 1 Page 1011 VGS1 + VSG 2 = 0.5mA( 4.4kΩ) = 2.2 V | Since the device parameters are the same, VGS1 = VSG 2 = 1.1 V | I D = 2 0.025 1.1−1) = 125 µA ( 2 −−− Since the device parameters are the same, VBE1 = VEB 2 = 0.5mA(2.4kΩ) 2 = 0.6 V  0.6  IC = 10−14 A exp  = 265 µA  0.025  ( € Page 1014 2 v Av1 = d = −g m n 2 RL = − 50mA/V 2 (2V −1V )(10) (8Ω) = −40.0 vg ( Avo = Av1 vo ≤ € ) 1 40.0 =− = −4.00 | n 10 ) v g ≤ 0.2(2 −1)V = 0.200 V | v d ≤ 0.2V ( 40) = 8.00 V 8V = 0.800 V 10 57 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1022  150(18.4kΩ)   = 32.5 MΩ RB → 0 | Rout = 432kΩ 1+  18.8kΩ + 18.4kΩ −−− 270kΩ VEQ = −15V = −10.66 V | REQ = 110kΩ 270kΩ = 78.2 kΩ 110kΩ + 270kΩ −10.66 − 0.7 − (−15) 195 µA IC = 150 = 195 µA | VB = VEQ − I B REQ = −10.66 − (78.2 kΩ) = −10.8 V 150 78.2kΩ + 151(18kΩ) 2 PR1 (−10.8 + 15) = PR E (−10.8 − 0.7 + 15) = Rout 110kΩ = 0.160 mW | PR 2 18kΩ (−10.8) = 2 270kΩ 2 = 1.33 mW | ro = = 0.432 mW (75 + 11.5)V = 446 kΩ 195µA | rπ = 150 = 19.3 kΩ 40(195µA)   150(18kΩ)   = 10.9 MΩ = 446kΩ 1+  78.2kΩ + 19.3kΩ + 18kΩ −−− 15V = 750kΩ | Using a spreadsheet with I o = 200 µA yields VBB = 9V. 20µA  9V  150  9 − 0.7 −1.33µA(180kΩ)    = 40.0 kΩ R1 = 750kΩ  = 450 kΩ | R1 = 300 kΩ | RE = 151  200µA  15V     75 + 15 − 8.3  150(40.0kΩ)   = 10.7 MΩ Rout =   1+  2x10−4  180kΩ + 18.75kΩ + 40.0kΩ R1 + R2 ≅ Page 1026 € VDS ≥ VGS − VTN = 1+ 2(0.2mA) 2.49mA/V 2 = 1.40 V | VD = VS + 1.40 = −15 + 0.2mA(18.2kΩ) + 1.40 = −9.96 V −−− W Kn 2.49mA /V 2 99.6 = = = L Kn' 1 25µA/V 2 € 58 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1027 2 PR S = (0.2mA) 18.2kΩ = 0.728 mW | I BIAS = 15V = 20.1 µA 499kΩ + 249kΩ 2 2 PR 4 = (20.1µA) 499kΩ = 0.202 mW | PR 3 = (20.1µA) 249kΩ = 0.101 mW 510kΩ = −10.2 V | −10.2 − VGS −18000I D = −15 V 510kΩ + 240kΩ 2 2.49mA 4.8 − VGS −18000 VGS −1) = 0 | VGS = 1.390 V | I D = 189 µA ( 2 VGG = −15V Rout ( ) 2 2.49x10−3 1 ≅ µ f RS ≅ 1+ 0.01(11.6) (18kΩ) = 10.3 MΩ 0.01 189x10−6 [ ] € 59 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 16 Page 1049 Ravg = 10kΩ(1+ 0.2) = 12 kΩ | 12kΩ(1− 0.01) ≤ R ≤ 12kΩ(1+ 0.01) | 11.88 kΩ ≤ R ≤ 12.12 kΩ Page 1051 € VDS1 = VTN + IO = 150µA 2I REF Kn (1+ λVDS1 ) 1+ 0.0133(10) 1+ 0.0133(2.08) | VDS1 = 1+ 2(150µA) 250µA/V 2 [1+ 0.0133VDS1] → VDS1 = 2.08 V = 165 µA −−− VDS ≥ VGS − VTN | VD − (−10V ) ≥ 2I D Kn | VD ≥ −10V + 2(150µA) 250µA /V 2 = −8.91 V Page 1052 € MR = 2(50µA) 1+ 0.02(15) 25 /1 = 8.33 | VDS1 = 1V + = 2.16 V | MR = 8.33 = 10.4 3/1 1+ 0.02(2.16) 3 25µA/V 2 MR = 2 /1 = 0.400 5 /1 ( | VDS1 = 1V + ) 2(50µA) ( 5 25µA/V 2 ) = 1.89 V | MR = 8.33 1+ 0.02(10) 1+ 0.02(1.89) = 0.463 Page 1054 €  V  V  VBE1 2  2  I REF = I S exp BE1 1+ BE1 + +  | 100µA = (0.1 fA) exp( 40VBE1 )1+  → VBE1 = 0.690  50V 100   VT  VA1 β FO  VCE ≥ VBE → VC ≥ −VEE + 0.690 V € € Page 1055 0.5 A 5A (a) MR = A = 0.5 | MR = 2 A = 2.50 0.5 2.50 (b) MR = 1.5 = 0.490 | MR = 3.5 = 2.39 1+ 1+ 75 75 15 15 1+ 1+ (c) MR = 0.5 0.7601.5 = 0.606 | MR = 2.5 0.7 60 3.5 = 2.95 1+ + 1+ + 60 75 60 75 60 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1056  10 /1  20 /1 IO2 = 100µA  = 200 µA | IO3 = 100µA  = 400 µA  5 /1   5 /1   40 /1  2.5 /1 IO4 = 100µA  = 800 µA | IO5 = 100µA  = 50 µA  5 /1   5 /1  −−− IO2 = 200µA IO4 = 800µA 1+ 0.02(10) 1+ 0.02(2) 1+ 0.02(12) 1+ 0.02(2) = 231 µA | IO3 = 400µA = 954 µA | IO5 = 50µA 1+ 0.02(5) 1+ 0.02(2) 1+ 0.02(8) 1+ 0.02(2) = 423 µA = 55.8 µA −−− 1 = 7.46 µA | IO 3 = 5( 7.46µA) = 37.3 µA | IO 4 = 10( 7.46µA) = 74.6 µA 17 1+ 50 10 10 1+ 1+ 50 50 IO2 = 10µA = 8.86 µA | IO 3 = 50µA = 44.3 µA 0.7 17 0.7 17 1+ + 1+ + 50 50 50 50 10 1+ 50 IO4 = 100µA = 88.6 µA 0.7 17 1+ + 50 50 IO2 = 10µA € Page 1057 10 10 − 9.957 MR = = 9.957 | FE = = 4.3x10−3 11 10 1+ 50(51) | VCE 2 = VBE1 + VBE 3 = 1.4 V € 61 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1058 MOS IO2 = 200µA IO3 = 400µA 1+ 0.02(10) 1+ 0.02(2) 1+ 0.02(5) 1+ 0.02(2) = 231 µA | Rout 2 = = 423 µA | Rout 3 = 50V + 10V = 260 kΩ 231µA 50V + 5V = 130 kΩ 423µA BJT 1+ IO2 = 10µA 10 50 = 10.1 µA | Rout 2 = 50V + 10V = 5.94 MΩ 10.1µA 0.7 17 + 50 100 10 1+ 50V + 10V 50 IO3 = 50µA = 50.7 µA | Rout 3 = = 1.19 MΩ 0.7 17 50.7µA 1+ + 50 100 1+ Page 1059 € 0.7V 10V 1+ 50V 50V IC1 = 100µA = 89.4 µA | IC 2 = 500µA 529µA 0.7V 6 0.7V 6 1+ + 1+ + 50V 50V 50V 50V 1 1 529µA 50V + 10V Rin ≅ = = 280 Ω | β = = 5.92 | Rout = = 113 kΩ g m1 40(89.4 µA) 89.4 µA 529µA 1+ Page 1060 € 10V VDS1 = VGS1 = 0.75V + = 1.20 V | I D 2 = 100µA 50V = 117 µA 1.2 1mA /V 2 1+ 50V 1 1 117µA 50V + 10V Rin ≅ = = 2.24 kΩ | β = = 1.17 | Rout = = 513 kΩ g m1 100µA 117µA 2 10−3 10−4 1+ 2(100µA) ( )( ) € 62 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1061 V I A  0.025V 100µA  R = T ln REF E 2  = ln 5 = 3000 Ω IO  IO AE1  25µA  25µA  100µA   75V  K = 1+ ln 5 = 4.00 | Rout = 4  = 12.0 MΩ  25µA   25µA  € Page 1062 V I A  0.025V  1000µA  IO = T ln REF E 2  | IO = ln  → IO = 300.54 µA R  IO AE1  100Ω  IO   100µA   75V  K = 1+ ln 10 = 2.202 | Rout = 2.202  = 550 kΩ  300.54 µA   300.54µA  Page 1063 €   2(200µA)  1 2I REF  IO (W/L)1  1 IO 1    IO = 1− | IO = 1− R Kn1  I REF (W/L)  2kΩ 25µA /V 2  200µA 10  2    IO   → IO = 764 µA IO = 2.00mA1− 2.00mA   Rout = € 50V + 10V   1+ 2000 2 2.5x10−4 7.64 x10−4  = 176 kΩ  764µA  ( )( ) Page 1066 β r 150  50V + 15V  50V + 15V Rout ≅ o o = = 1.30 MΩ   = 97.5 MΩ | Rout = ro = 2 2  50µA  50µA Page 1068 € VDS 2 = VGS 2 = 0.8V + ( ( 2 5x10−5 ) = 1.43 V 2.5x10−4 )( Rout ≅ µ f 4 ro2 = 2 2.5x10−4 5x10−5 Rout = ro = | VDS 4 = 15 −1.43 = 13.6 V  1  1  V + 13.6V  V + 1.43V   1+ 0.015(13.6)  0.015  0.015  = 379 MΩ 50 µ A 50µA       )[ ] 66.7V + 15V = 1.63 MΩ 50µA −−− Rout ≅ β oro 100  67V + 14.3V  67V + 15V = = 1.64 MΩ   = 81.3 MΩ | Rout = ro = 2 2  50µA  50µA 63 € ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1072 IO = 25.014µA + 10V − 20V = 25.008 µA 1.66GΩ −−− VDS 4 ≥ VGS 4 − VTN = 0.2 V | VD 4 ≥ VS 4 + 0.2V | VD 4 ≥ 0.95 + 0.2 = 1.15 V −−− 20V = 400 MΩ | Choose Rout = 1 GΩ. 50nA 2  0.01  50µA 50V 1 2Kn mA ro ≅ = 1 MΩ → µ f = 1000 | µ f ≅ | Kn =  1000) = 2.5 2 ( 50µA λ ID V  V  2 2.5x10−3 50 1  50  25 (W / L)2 = (W / L)4 = 5x10−5 = 1 | (W / L)3 = (W / L)1 = 2  1  = 1 IO = 50µA ± 0.1% € | ΔIO ≤ 50 nA | Rout ≥ Page 1073 5V − 0.7V 7.5V − 0.7V I REF = = 100 µA | I REF = = 158 µA 43kΩ 43kΩ −−− Since the transistors have the same parameters, VGS1 = VDD − (−VSS ) 3 2 2 4 x10 4 x10−4 I D2 = I D1 = 1.667 −1 = 89.0 µ A | I = I = 2.5 −1) = 450 µA ( ) ( D2 D1 2 2 −−− 0.025V 5 −1.4 0.025V 7.5 −1.4 IO ≅ ln −16 = 101 µA | IO ≅ ln −16 = 103 µA 6.8kΩ 10 (39kΩ) 6.8kΩ 10 (39kΩ) −4 € Page 1074 V I A  0.025V IO = T ln C1 E 2  | IO = ln 10(10) = 115 µA R  IC 2 AE1  1000Ω −−− VCC + VEE ≥ VBE1 + VBE 4 ≅ 1.4 V [ ] Page 1076 € R= 2 ( )( ) 5 25x10−6 10−4  5 1−  = 8.65 kΩ 50   € 64 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1077 V  I A  0.025875V  25  R = T ln C1 E 2  = ln  = 925 Ω IO  IC 2 AE1  45µA 5 AE1 = A | AE 2 = 25 AE1 = 25 A | AE 3 = A | AE 4 = 5.58 AE 3 = 5.58 A Page 1081 € A  V 82.59mV VPTAT = VT ln E 2  = (27.57mV ) ln (20) = 82.59 mV | R1 = PTAT = = 3.30 kΩ IE 25µA  AE1  I   25µA  VBE1 = VT ln C1  = (27.57mV ) ln  = 0.6792 V  0.5 fA   I S1  R2 VGO + 3VT − VBE1 1.12 + 3(0.02757) − 0.6792 = = = 3.169 R1 2VPTAT 2(0.08259) VBG = VBE1 + 2 | R2 = 3.169R1 = 10.5 kΩ R2 VPTAT = 0.6792 + 2(3.169)(0.08259) = 1.203 V R1 The other resistors remain the same. Page 1084 € I D3 = I D 4 = I D1 = I D 2 = VGS 3 = −0.75V − 2(125µA) 250µA = 125 µA | VGS1 = 0.75V + = 1.75 V 2 250µA /V 2 2(125µA) 200µA/V 2 = −1.87 V VDS1 = VD1 − VS1 = (5 −1.87) − (−1.75) = 4.88 V | VSD 3 = VSG 3 = 1.87 V M1 and M 2 : (125 µA, 4.88 V ) ( | M 3 and M 4 : (125 µA, 1.87 V ) )( ) Gm = g m1 = 2 2.5x10−4 1.25x10−4 = 250 µS Ro = ro2 ro4 = 75.2V + 4.88V 75.2V + 1.87V = 314 kΩ | Av = Gm Ro = 78.5 125µA 125µA Page 1085 €  1 2K   1 2K  n3 n3  2Kn2 I D 2 RSS =   2Kn2 I D 2 RSS CMRR ≅ µ f 3 g m2 RSS =  λ I λ I D3  D3    1 Kn3 = Kn2 | I D 2 = I D 3 | CMRR = 2(0.005)10 7 = 5.99x10 6 or 136 dB 0.0167 ( ) ( ) € 65 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1089 For the buffered current mirror, VEC 4 = VEB 3 + VEB11 + IC11 ≅  I  | ΔVEB = 0.025 ln C 4  = 80.5 mV  IC 4 / 25  2IC 4 2IC 4 IC 4 = = β FO 4 50 25 VEC 4 = 0.7 + (0.7 − 0.081) + € 2VA β FO 4 (β FO11 + 1) 2(60) 50(51) = 1.37 V | ΔVEC = 2(60V ) 50(51) = 47.1mV | VOS = 47mV = 0.47 mV 100 Page 1090  I  150 Av1 ≅  β o5 C 2  = = 50 IC 5  3  −−− For the whole amplifier : Adm ≅ Av1 Av 2 Av3 Adm ≅ 50( 3000)(1) = 150000 | Av 2 ≅ µ f 5 ≅ 40(75) = 3000 | Av 3 ≅ 1 | Note that this assumes R L = ∞. Page 1091 −1 € −1     2  1  1 2  1 1   = 5.45x10 6 →135 dB CMRR =   −  = − −4 7 100  100( 40)(75) 2( 40) 10 10  β o3  β o2µ f 2 2g m2 REE     ( )( ) Page 1096 € Adm ≅ Av1 Av 2 Av 3 | Av1 ≅ 40(60 + 14.7) µ IC 2 I β 50 β o5 = REF o5 = = 5 | Av 2 ≅ f 5 ≅ ≅ 1500 | Av 3 ≅ 1 IC 5 2 5I REF 10 2 2 Adm ≅ 5(1500)(1) = 7500 assuming the input resistance of the emitter followers is much greater than ro5 and VA 8 = VA 5. Checking : ro5 ≅ IC 5 = 10IC 4 = 10IC 3 → AE 5 = 10 A 60V + 14.7V = 149 kΩ | RiB 6 ≅ β o6 RL = 300 MΩ 500µA 150 | Rid = 2rπ 1 = 2 = 150 kΩ 40(50µA) € 66 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1098 22 + 22 −1.4 0.025V  1.09mA  I REF = = 1.09 mA | I1 = ln  → I1 = 20.0 µA 39kΩ 5kΩ  I1  23.4V 21.3V 1+ 1+ 60V 60V I 2 = 0.75(1.09mA) = 1.08 mA | I 2 = 0.25(1.09mA) = 351 µA 0.7V 2 0.7V 2 1+ + 1+ + 60V 50 60V 50 −−−   733µA  I A  60V + 13.5V  Ro = ro211+ ln C 20 E 20  = 1 = 18.7 MΩ 1+ ln IC 21 AE 21  18.4 µA   18.4 µA   Page 1102 € VCE 6 = VCE 5 + 2(60V ) 2VA 6 = 0.7 + = 1.90 V β FO6 100 Page 1105 € €  60 + 13   60 + 1.3 Rth = Rout 4 Rout 6 = 2ro4 1.3ro6 = 2  1.3  = 20.1MΩ 11.1MΩ = 7.15 MΩ  7.25µA   7.16µA  Page 1107 Av1 = −1.46x10−4 6.54 MΩ Rin11 = −1.46x10−4 6.54 MΩ 20.7kΩ = −3.01 ( ) ( ) Page 1109 € Req 2 = rπ 15 + (β o15 + 1) RL = Req1 = rd14 + (rd13 + R3 ) 50(0.025) + 51(2kΩ) = 103 kΩ 2mA  0.025V  0.025V Req 2 = + + 344kΩ 103kΩ = 79.4 kΩ 0.216mA  0.216mA  50(0.025V ) + 51( 79.4kΩ) = 4.06 MΩ 0.216mA −1      0.025V r + y22 0.025V 5.79kΩ + 89.1kΩ  Req 3 = (rd13 + R3 )  rd14 + π 12 + 344kΩ  +  =  = 1.97 kΩ β o12 + 1   0.216mA 51   0.216mA   Rin12 = rπ 16 = 50 0.025 625 + 1970 = 625 Ω | Rout = + 27 = 78 Ω 2mA 51 −−− I SC + ≅ € 0.7V 0.7V = 25.9 mA | I SC − ≅ − = −31.8 mA 27Ω 22Ω 67 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1112  R  vo vo 5 1 vo =  = 2 = 0.2 | K M = = 2 =1 v1v 2 = K M v1v 2 | K M = v1v 2 5 v1v2 1  I EE R1 R3  € 68 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 17 Page 1131 2 2 2 2 1 1 fL ≅ 10 2 + 1000 2 − 2(50) − 2(0) = 159 Hz | f L ≅ 100 2 + 1000 2 − 2(500) − 2(0) = 114 Hz 2π 2π Page 1132 € € € € 200s( s + 100) 200s ≥ 0.9 (s + 1000) (s + 10)(s + 1000) | 1 ≥ 0.9 ω 2 + 100 2 ω 2 + 10 2 → 0.81 ≤ ω 2 + 10 2 → ω ≥ 205 rad/s ω 2 + 100 2 Page 1133 10 6 fH ≅ = 159 kHz 2π Page 1134 1 1 fH ≅ = 21.7 kHz 2 2 2 2 2π         1 1 1 1 − 2 − 2   5 + 5 5 10   5x10   2x10  ∞ Page 1139 The value of C3 does not change A mid , ω P1, ω P2 , ω z1 , or ω Z2 . ωP3 = − fL = 1 2π 1 1 = −1000 rad/s | ω Z 3 = − = −385 rad/s   2µF (1.3kΩ) 1 2µF 1.3kΩ  1.23mS   ( ) 41.0 2 + 95.9 2 + 1000 2 − 2 0 2 + 0 2 + 385 2 = 135 Hz −−− 13.5 4.732 → ro = 57.5 kΩ 1.23mS Note that the SPICE value of gm probably differs from 1.23 mS as well. Amid = 10 20 = 4.732 | 4.3kΩ 100kΩ ro = −−− ωP3 = − fL = € 1 2π 1 = −202 rad/s   1 10µF 1.3kΩ 57.5kΩ 1.23mS   ( ) 41.0 2 + 95.9 2 + 202 2 − 2 0 2 + 0 2 + 76.9 2 = 31.8 Hz 69 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1142 140(0.025V ) rπ = = 20.0 kΩ | R1S C1 = 1kΩ + 75kΩ 20.0kΩ 2µF = 33.6 ms | Rth = 75kΩ 1kΩ = 987 Ω 175µA  20.0kΩ + 987Ω  R2S C2 = ( 43kΩ + 100kΩ)0.1µF = 14.3 ms | R3S C3 = 13kΩ 10µF = 1.47 ms 141   1  1 1 1  fL ≅ + +   = 124 Hz 2π  33.6ms 1.47ms 14.3ms  ( € ) Page 1144 Rin  β o   1260  100  Av = −  RL  ≅ −   4.3kΩ 100kΩ = −157 RI + Rin  rπ   2260 1.51kΩ  Rin  β o   1260  100  Av = −  RL  ≅ −   4.3kΩ 100kΩ 46.8kΩ = −140 RI + Rin  rπ   2260 1.51kΩ  ( ) ( ) ro is responsible for most of the discrepancy. rπ and βo will also be differ from our hand calculations. Note that 45% of the gain is lost because of the amplifier's low input resistance. −−− gm = 2(1.5mA) 0.5V = 6.00 mS | R1S C1 = (1kΩ + 243kΩ)0.1µF = 24.4 ms  1  R2S C2 = ( 4.3kΩ + 100kΩ)0.1µF = 10.4 ms | R3S C3 = 1.3kΩ 10µF = 1.48 ms 6.00mS   1  1 1 1  fL ≅ + +   = 129 Hz 2π  24.4ms 1.48ms 10.4ms  Page 1146 € €  1  g m = 40(0.1mA) = 4.00 mS | R1S C1 = 100Ω + 43kΩ  4.7µF = 1.64 ms 4.00mS   1  1 1  R2S C2 = (22kΩ + 75kΩ)1µF = 97.0 ms | f L ≅ +   = 98.7 Hz 2π  1.64ms 97.0ms  Page 1147  2(1.5mA) 1  gm = = 6.00 mS | R1S C1 = 100Ω + 1.3kΩ 1µF = 0.248 ms 0.5V 6.00mS   R2S C2 = ( 4.3kΩ + 75kΩ)0.1µF = 7.93 ms | fL ≅ 1  1 1  +   = 662 Hz 2π  0.248ms 7.93ms  € 70 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1148 100 = 2.50 kΩ .04S   R1S C1 = 1kΩ + 100kΩ 2.5kΩ + 101 3kΩ 47kΩ 0.1µF = 7.52 ms    2.5kΩ + 100kΩ 1kΩ   100µF = 4.70 s | f ≅ 1  1 + 1  = 21.2 Hz R2S C2 = 47kΩ + 3kΩ   L   101 2π  7.52ms 4.7s    g m = 40(1mA) = 40.0 mS | rπ = [ ( Amid ≅ (β )] ( ) ( + 1) RL ) 101 3kΩ 47kΩ  RI   = Rth + rπ + (β o + 1) RL  RI + RB  990Ω + 2.5kΩ + 101 3kΩ 47kΩ o ( )  100kΩ    = +0.978  1kΩ + 100kΩ  −−−  1  R1S C1 = (1kΩ + 243kΩ)0.1µF = 24.4 ms | R2S C2 = 24kΩ + 1.3kΩ  47µF = 1.15 s 1mS   1  1 1  fL ≅ +   = 6.66 Hz 2π  24.4ms 1.15s   RG  g m RL  243kΩ   1mS 1.3kΩ 24kΩ   = +0.550 Amid = + = +    R + R 1+ g R 244kΩ   1+ 1mS 1.3kΩ 24kΩ   I G m L ( ) ( € Page 1152 g Cπ = m − Cµ ωT Cµo Cµ = VCB ϕ jc 1+ (100 µA, 8 V ) : 2 pF Cµ = 1+ (2 mA, 5 V ) : Cµ = Cµ = 7.3V 0.6V 2 pF 1+ (50 mA, 8 V ) : ) 4.3V 0.6V 2 pF 1+ 7.3V 0.6V = 0.551 pF | Cπ = = 0.700 pF | Cπ = ( ) 40 10−4 2π (500 MHz) ( 40 2x10−3 ) 2π (500 MHz) = 0.551 pF | Cπ = ( 40 5x10−2 − 0.551x10−12 = 0.722 pF − 0.700x10−12 = 24.8 pF ) 2π (500 MHz) − 0.551x10−12 = 636 pF € 71 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1155 1 CGS = CGD = CISS = 0.5 pF 2 −−− CGS + CGD = gm ωT | 5CGD + CGD = 2(0.01)(0.01) 2π (200 MHz) = 11.3 pF | CGD = 1.88 pF | CGS = 9.38 pF −−− Cµ = Cµo 1+ € VCB ϕ jc = 2 pF 1+ 7.3V 0.6V = 0.551 pF | Cπ = 40(20µA) gm − Cµ = − 0.551pF = −0.296 pF ωT 2π (500 MHz) Page 1158  Rin  β o Av = − RL  | Rin = 7.5kΩ (1.51kΩ + 250Ω) = 1.43kΩ  RI + Rin  rx + rπ   1430  100  ≅ −   4.3kΩ 100kΩ = −139  2430 1.76kΩ  Rin  β o   1260  100  Av = −  RL  ≅ −   4.3kΩ 100kΩ = −157 RI + Rin  rπ   2260 1.51kΩ  ( ) ( ) Page 1166 € RL is added to the value of CT . rπo  4120  R 1 CL L = 3 pF  = 1.39 MHz  = 18.8 pF | f P1 = rπo 2π (656Ω)(156 + 18.8) pF  656  The term CL fP 2 = gm 0.064S = = 445 MHz 2π (Cπ + CL ) 2π (19.9 + 3) pF −−− Cπ = 0.064 −10−12 = 19.4 pF 2π (500 MHz)  4120  1 CT = 19.4 + 11+ 0.064 ( 4120) + = 837 kHz  = 290 pF | f P1 = 656  2π (656Ω)290 pF  fP 2 = gm 0.064S g 0.064S = = 525 MHz | f Z = m = = 10.2 GHz 2πCπ 2π (19.4 pF ) 2πCµ 2π (1pF ) Amid = −135 is not affected by the value of f T . € 72 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1167  4120  1 CT = 10 + 2 1+ 1.23mS ( 4.12kΩ) + = 5.26 MHz  = 30.4 pF | f P1 = 996  2π (996Ω) 30.4 pF  fP 2 = fT = € gm 1.23mS gm 1.23mS = = 19.6 MHz | f Z = = = 97.9 MHz 2πCGS 2π (10 pF ) 2πCGD 2π (2 pF ) gm 1.23mS = = 16.3 MHz 2π (CGS + CD ) 2π (12 pF ) Page 1174 1+ g m RE = 1+ 0.064 (100) = 7.40 | RiB = 250 + 1560 + 101(100) = 11.9 kΩ rπ 0 = 11.9kΩ (882 + 250) = 1030 Ω | Ai =  264  Amid = −0.821  = −29.3 | f H =  7.4  10kΩ 30kΩ 11.9kΩ 1kΩ + 10kΩ 30kΩ 11.9kΩ = 0.821 1 = 6.70 MHz 19.9 pF  264 4120  2π (1.03kΩ) + 0.5 pF 1+ +  7.4 1030    7.4 GBW = 29.3(6.70 MHz) = 196 MHz € Page 1176 g m′ RL Amid ≅ 1+ g m′ RE fH ≅ | g m′ = βo = rx + rπ 3.96mS (17.0kΩ) 100 = 3.96 mS | Amid ≅ = +48.2 100 1+ 3.96mS (100Ω) 250 + 40(0.1mA) 1 = 18.7 MHz | GBW = 903 MHz 2π (17.0kΩ)(0.5 pF ) −−− RiS = R4 1 1 = 1.3kΩ = 265 Ω gm 3mS Amid = 0.726( g m RL ) = 0.726( 3mS )(4.12kΩ) = 8.98 GBW = 86.7 MHz | f T ≅ | fH ≅ 1 = 9.66 MHz 2π ( 4.12kΩ)( 4 pF ) 3mS = 43.4 MHz 2π (11pF ) € 73 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1179 RL = 1.3kΩ 24kΩ = 1.23kΩ | Amid = 0.998 1 2π fH ≅ 1  10 pF  1kΩ 430kΩ 1pF +  1+ 3.69   ( 3mS (1.23kΩ) 1+ 3mS (1.23kΩ) = 0.785 = 50.9 MHz ) Page 1182 € € fZ = 1 1 = 6.37 kHz | f P = = 6.33 MHz 2π (25 MΩ)1pF 2π (50.25kΩ)0.5 pF Page 1184 Differential Pair : Adm = −g m RC = −40(99.0µA)(50kΩ) = −198 Cπ = 40(99.0µA) 2π (500 MHz) − 0.5 pF = 0.761 pF | rπ = 100 = 25.3 kΩ 40(99.0µA) 1 fH = = 3.18 MHz   50kΩ  2π (250Ω)0.761pf + 0.5 pF 1+ 198 +  250Ω     1  g m1  198  g m2  CC − CB Cascade : Av = g m RC ) = + = +99.0 (  1  2 1+ g m1   g m2  fH ≅ 1 = 6.37 MHz 2π (50kΩ)(0.5 pF ) Page 1185 € g m = 40(1.6mA) = 64.0 mS | rπ = Amid = 100 64.0mS = 1.56 kΩ | Cπ = − 0.5 pF = 19.9 pF 64mS 2π (500 MHz) rπ 1.56 kΩ −g m RL ) = ( (−64.0mS )(4.12kΩ) = −153 RI + rx + rπ 882Ω + 250Ω + 1.56 kΩ f P1 ≅ 1 1 = = 11.6 MHz 2π rπ 0 (Cπ + 2Cµ ) 2π (656Ω)(19.9 + 1) pF fP 2 ≅ 1 1 = = 7.02 MHz 2π RL (Cµ + CL ) 2π (4120Ω)(0.5 + 5) pF € 74 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1186 f P1 ≅ 0.02(100µA) 0.02(25µA) 1 1 = = 159 kHz | f P1 ≅ = = 39.8 kHz 4 π CGGDro2 4 π CGGDro2 4 π (1pF) 4 π (1pF) Page 1193 € XC = 1 = 7.69 MΩ >> 2.39 kΩ 2π (530Hz)39 pF XC = 1 = 300 MΩ | 51.8kΩ 19.8kΩ = 14.3 kΩ | 300 MΩ >> 14.3 kΩ 2π (530Hz)1pF −−− X1 = 1 1 = 23.9 Ω << 1.01 MΩ | X 2 = = 5.08 mΩ << 66.7 Ω 2π (667kHz)0.01µF 2π (667kHz)47µF X3 = 1 = 239 mΩ << 2.69 kΩ 2π (667kHz)1µF Page 1198 € ZC = 1 = − j3.18 Ω 2π j (5MHz)0.01µF Page 1199 € (i ) Q= fo = 1 2π (10µH )(100 pF + 20 pF ) 100kΩ 100kΩ ro 2π (4.59 MHz)(10µH ) ( = 49.2 = 4.59 MHz | ro = | BW = 50V + 15V −1.6V = 19.8 kΩ 3.2mA 4.59 MHz = 93.3 kHz 49.2 ) ( ) Amid = −g m 100kΩ 100kΩ ro = − 2(0.005)(0.0032) 100kΩ 100kΩ 19.8kΩ = −80.2 −−− f o is unchanged | ro = € € 100kΩ 100kΩ ro 50V + 10V −1.6V = 18.3 kΩ | Q = = 46.4 3.2mA 2π (4.59 MHz)(10µH ) Page 1203  C   C  L gm REQ = g m S = LS 1+ GD  = ωT LS 1+ GD  CGS CGS + CGD  CGS   CGS  REQ ≅ ωT LS for CGS >> CGD 75 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1204 LS ≅ € € € REQ ωT = L2 REQ µn (VGS − VTN ) Page 1207 1 A 1 ACG = = Aπ π = (5x10 (400cm 2 −5 ) 2 cm 75Ω ) V − s (0.25V ) = 1.88x10-9 H 1 | 20log  = −9.94 dB π  Page 1209 1 2A 2 ACG = = A π π  2 | 20log  = −3.92 dB π  Page 1210 From Fig. 17.81(a), the amplitude of the output signal is approximately 70 mV, so the conversion gain is approximately:  200mV  1.4 1.4  1 0.7) | 20log  = −7.02 dB = ( 100mV  π  π π  From Fig. 17.81(b), the spectral components at 46 and 54 kHz have amplitudes of approximately 45 mV, so the conversion gain is: ACG = € ACG = 45mV 1.4 = 0.45 | 20log(0.45) = −6.93 dB | Note : = 0.446 100mV π Page 1212 € fC − f m = 20 − 0.01 = 19.99 MHz | f C + f m = 20 + 0.01 = 10.01 MHz 3 f C − f m = 60 − 0.01 = 59.99 MHz | 3 f C + f m = 60 + 0.01 = 60.01 MHz 5 f C − f m = 100 − 0.01 = 99.99 MHz | 5 f C + f m = 100 + 0.01 = 100.01 MHz −−− AfC + f m = AfC − f m = 3 V A3 f C + f m = A3 f C − f m = A5 f C + f m = A5 f C − f m = Af C − f m 3 Af C − f m 5 =1 V = 0.6 V € 76 ©R. C. Jaeger and T. N. Blalock 09/25/10 CHAPTER 18 Page 1231 I1 = 1 mA | VCE 2 = 0.7 V | VEC3 = 0.7 V | VO = 0 V 2 VEC 4 = 5V − VO = 5 − 0 = 5.0 V | VEC1 = 5 − VC1 − VE1 = 5 − 0.7 − (−0.7) = 5.0 V IC 4 = IC 3 = IC 2 = IC1 = (1 mA, 5.0 V ), (1 mA, 0.7 V ), (1 mA, 0.7 V ), (1 mA, 5.0 V ) € Page 1234 With the output shorted, current cannot make it around the loop, so TSC = 0. −−− TOC = 0 is zero only if ro1 is neglected since the votlage across rπ must be zero for ib = 0. If we include ro1, and start at the base of Q2 assuming ro1 >> vc4 ≅ T≅ 1 and a current mirror gain of 1: g m3  v e1 g r  1  1) ro4 RiB 2 RL ro4 (1+ g m2ro1 ) =  vb2 m2 o1   ro4 RiB 2 RL ( ro1  1+ g m2ro1  ro1  [ ro4 RiB 2 RL ro1 ] = 55kΩ 5.1kΩ 10kΩ 55kΩ [ ] = 0.0579 −−− ( ) ( ) Evaluating Eq. 18.7 without RL , TOC = g m2 ro1 ro1 RiB 2 = 0.04 55kΩ 55kΩ 5.1kΩ = 172 Page 1239 € [ ( Tnew = g m1 R3 rπ 2 Tnew = Told R3 rπ 2 R3 RiB 2 )][−g ([ R + R m2 (1+ g m2 2 1 RiE1 ]  R R  1 iE1   R5 RL   R R + R 2  1 iE1 )] 1kΩ 2.5kΩ R4 ) = −2.01 1+ 0.04S (300Ω) = −19.2 970Ω [ ] 19.2 D = 9.50 | Now RiC2 = ro2 = ∞ | RinD ≅ 31.7 kΩ | Rout ≅ 1.74 kΩ 1+ 19.2 1.86  1+ 17.8 Scaling using the previous result : TSC = −19.2 = 596kΩ  = 17.8 | Rin = 31.7kΩ 1+ 0  2.01 Av = 10 Rout −1  1 1+ 0 1  ′ = = 1.74kΩ = 86.1 Ω | Removing RL : Rout −  = 86.8 Ω 1+ 19.2  86.1 10 4  € 77 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1241 1+ TSC Rx = RxD 1+ TOC | RxD = R3 RiD1 RiG3 = R3 2ro1 RiG3 = 3kΩ ∞ ∞ = 3kΩ  1+ 0  TSC = 0 | TOC = T = 61.1 | Rx = 3kΩ  = 48.3 Ω  1+ 61.1 −−− I D2 = I D1 = 1.63V − (−5V ) I1 = 0.500 mA | I D4 = I2 = 2.00 mA | I D3 = = 0.510 mA 2 13kΩ 2(0.5mA) VDS1 = 3.5 + VGS1 | VGS1 = 1+ = 1.32 V | VDS1 = 3.5 + 1.32 = 4.82 V 10mA VDS2 = 5 + 1.32 = 6.32 V | VDS 3 = 5 −1.63 = 3.37 V | VDS 4 = 5 − VO = 5.00 V (0.5 mA, 4.82 V ), (0.5 mA, 6.32 V ), (0.51 mA, 3.37 V ), (2 mA, 5.0 V ) € Page 1245 Ri appears in parallel with rπ : rπ′ = rπ Ri = 4.69kΩ 10kΩ = 3.19 kΩ  r′    3.19kΩ T = −g m RC ( RF + rπ′ ) ro  π  = −0.032S 5kΩ (50kΩ + 3.19kΩ) 62.4kΩ   = −8.17  3.19kΩ + 50kΩ   rπ′ + RF  T 8.17 Atr = AtrIdeal = −50kΩ = −44.5 kΩ 1+ T 1+ 8.17 RinD = rπ′ RF + RC ro = 3.19kΩ 50kΩ + 5kΩ 62.4kΩ = 3.01 kΩ | TSC = 0 | TOC = T ( ( ) ) ( ) ( ) 1+ 0 = 328 Ω 1+ 8.17 = RC ro ( RF + rπ′ ) = 5kΩ 62.4kΩ (50kΩ + 3.19kΩ) = 4.26 kΩ Rin = 3.01kΩ D Rout Rout = 4.26kΩ | TSC = 0 | TOC = T 1+ 0 = 463 Ω 1+ 8.17 € 78 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1246  R  R   45.1kΩ   10kΩ F L Av = −   = −   = −18.6  Ri + Rin  Rout + RL   2kΩ + 340Ω  336Ω + 10kΩ   R  R   45.1kΩ   2kΩ F L Av = −   = −   = −3.73  Ri + Rin  Rout + RL  10kΩ + 340Ω  336Ω + 2kΩ  −−− − Atr 48.5kΩ 1  1  1  1  = = 32.3 | g m3 =  =   = 2.50 mS RF + Atr 50kΩ − 48.5kΩ Rout  1+ T  12Ω 1+ 32.3   1  1   1  1  Rin =  RF +   =  50kΩ +   = 1.51 kΩ g m3  1+ T   2.5mS  1+ 32.3   T= Page 1250 € T is the same : T = 306. D Rout = RF | AvIdeal = 1 | Av = AtrIdeal 1 1 = 10kΩ = 307 Ω g m5 3.16mS Rout = 307Ω |  306  T = 1  = 0.997 1+ T 1+ 306  TSC = 0 | TOC = T 1+ 0 = 1.00 Ω 1+ 306 Page 1251 € T is the same : T = 306. | AvIdeal = 1 | Av = AtrIdeal  2  1 1 RinD = ro11+ g m1 = 600kΩ = 500 Ω  g m2  g m3 2.00mS   306  T = 1  = 0.997 1+ T 1+ 306  | TOC = 306 Note : The impedance looking in the source of a transistor with a high resistance load of ro is 2/g m rather than 1/gm . TSC = − 3.16mS (10kΩ) g m2 g m5 RF 3.16mS 2ro2 ro4 =− 400kΩ 200kΩ = −204 2 1+ g m5 RF 2 1+ 3.16mS (10kΩ) ( Rout = 500Ω ) ( ) 1+ 204 = 334 Ω 1+ 306 € 79 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1254 T is the same : T = 152. D Rout = ( R2 + RI ) R1 Rout = 304Ω | AvIdeal = −  152  R2 T = −1 | Av = AtrIdeal = −1  = −0.993 RI 1+ T  1+ 152  1 1 = 40kΩ 10kΩ = 304 Ω g m5 3.16mS | TSC = 0 | TOC = T = 152 1+ 0 = 1.99 Ω 1+ 152 Page 1255 € There are approximately 15 cycles in 0.8 µsec : f ≅ 15cycles = 18.8 MHz 0.8us Page 1256 € fT = 1 gm 2π CGS + CGD fT 3 = 1 2π | g m = 2Kn I D 2(0.004)(0.0005) 5 pf + 1pF | f T 2 = fT1 = = 53.1 MHz | fT 4 = 1 2π 1 2π 2(0.01)(0.0005) 5 pf + 1pF 2(0.01)(0.002) 5 pf + 1pF = 83.9 MHz = 168 MHz Page 1265 € ( )( ) Gm = g m2 = 2 10−3 5x10−5 = 0.316 mS | Ro = ro4 ro2 ≅ fT = 1 1 = = 500 kΩ 2λI D 2(0.02)5x10−5 1  Gm  1  0.316mS   =   = 2.51 MHz 2π  CC  2π  20pF         1   1 1  1 1 1   = 158 Hz  =  ≅ fB =   2π  RoCC (1+ Av2 )  2π  RoCC (1+ µ f 2 )  2π  2(0.001)  500kΩ(20pF)1+ 1  0.02 5x10−4      € 80 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1266 1 g m5 1 fz ≅ = 2π CC 2π 2(0.001)5x10−4 20x10 −12 = 7.96 MHz | R = 1 1 = = 1.00 kΩ g m5 2(0.001)5x10−4 −−− ( ) Gm = g m2 = 40 5x10−5 = 2.00 mS | Ro = rπ 5 ≅ 100V ( ) 40 5.5x10−4 A = 4.54 kΩ −4  1  Gm  1  2.00mS  1  g m5  1  40 5x10 fT =  =  =   = 10.6 MHz | f Z = 2π  CC  2π  30pF  2π  CC  2π  3x10−11  (  1  1  1 1   ≅ fB = 2π  rπ 5CC (1+ µ f 2 )  2π 4.54kΩ(30pF) 1+ 40(50)  [ € ] ) = 106 MHz     = 584 Hz   Page 1269 100µA V V SR = = 5.00x106 = 5.00 20 pF s µs −−− 100µA V V SR = = 5.00x106 = 5.00 20 pF s µs Page 1273 € ( ) Gm = g m2 = 40 2.5x10−4 = 10.0 mS | f T = 1  Gm / 2  1  10.0mS   =   = 15.7 MHz 2π  CC + Cµ3  4π  50.8pF   15.7 MHz        −1 15.7 MHz −1 15.7 MHz −1 15.7 MHz o φ M = 90 − tan−1  + tan   + tan   + tan   = 69.5  142 MHz   173MHz   192 MHz   206 MHz  € Page 1277 I1 1mA V V SR ≅ = = 15.4x106 = 15.4 CC + CGD5 65 pF s µs −−−      fT fT fT  −1 −1 30 o = tan−1  + tan   + tan   → f T = 16.6 MHz  49.2 MHz   82.1MHz  100 MHz   8.5MHz  CC = 65 pF   − 2 pF = 31.3 pF  16.6 MHz  € 81 ©R. C. Jaeger and T. N. Blalock 09/25/10 Page 1283 When the circuit is drawn symmetrically, capacitor 2CGD is replaced with 2 capacitors of value 4CGD in series. The circuit can then be cut vertically down the middle to form a differential mode half-circuit. The total capacitance at the drain end of inductor L is C+CGS+4CGD. Page 1285 fP = 1 1 = 5.016 MHz | f P = = 5.008 MHz  31.8 fF (7 pF )  31.8 fF (25 pF )    2π 31.8mH  2π 31.8mH   7.0318 pF   25.0318 pF  € 82 ©R. C. Jaeger and T. N. Blalock 09/25/10 MICROELECTRONIC CIRCUIT DESIGN Fourth Edition Richard C. Jaeger and Travis N. Blalock Answers to Selected Problems – Updated 2/27/11 Chapter 1 1.4 1.52 years, 5.06 years 1.5 1.95 years, 6.46 years 1.8 402 MW, 1.83 MA 1.10 2.50 mV, 5.12 V, 5.885 V 1.12 19.53 mV/bit, 100110002 1.14 14 bits, 20 bits 1.16 0.003 A, 0.003 cos (1000t) A 1.19 vDS = [5 + 2 sin (2500t) + 4 sin (1000t)] V 1.20 15.7 V, 2.32 V, 75.4 µA, 206 µA 1.22 150 µA, 150 µA, 12.3 V 1.24 39.8 Ω, 0.0251 vs 1.27 56 kΩ, 1.60 x 10-3 vs 1.29 1.50 MΩ, 7.50 x 108 ii 1.36 50/−12°, 10/−45° 1.38 -82.4 sin 750πt mV, 11.0 sin 750πt µA 1.40 1 + R2/R1 1.42 -1.875 V, -2.500 V 1.43 Band-pass amplifier 1.45 50.0 sin (2000πt) + 30.0 cos (8000 πt) V 1.48 0V 1.47 [4653 Ω, 4747 Ω], [4465 Ω, 4935 Ω], [4230 Ω, 5170 Ω] 1.55 6200 Ω, 4.96 Ω/oC 1.61 3.29, 0.995, −6.16; 3.295, 0.9952, −6.155 2 Chapter 2 ! ! 2.3 500 mA 2.4 160 Ω, 319 Ω 2.6 For Ge : 2.63 x 10-4 / cm 3 , 2.27 x 1013 / cm 3 , 8.04 x 1015 / cm 3 , 2.9 305.2 K 2.10 "1.75x10 6 cm s , + 6.25x10 5 cm s , 2.80x10 4 A cm 2 , 1.00x10"10 A cm 2 2.11 1.60 x 106 A/cm2, 1.60 x 10-10 A/cm2 2.13 4 ΜΑ/cm2 2.16 1.60 x 107 A/cm2, 4.00 A 2.17 316.6 K 2.22 Donor, acceptor 2.23 200 V/cm 2.25 1.25 x 104 atoms 2.27 p-type, 6 x 1018/cm3, 16.7/cm3, 5.28 x 109/cm3, 8.80 x 10-10/cm3 2.29 3 x 1017/cm3, 333/cm3 2.30 4 x 1016/cm3, 2.50 x 105/cm3 2.34 40/cm3, 2.5x1018/cm3, 170 cm2/s, 80 cm2/s, p-type, 31.2 mΩ-cm 2.36 1016/cm3, 104/cm3, 800 cm2/s, 220 cm2/s, n-type, 2.84 Ω-cm 2.38 1.16 x 1020/cm3 2.40 1.24 x 1019/cm3 2.41 Yes—add equal amounts of donor and acceptor impurities. Then n = ni = p, but the mobilities are reduced. See Prob. 2.44. 2.43 6.27 x 1021/cm3, 6.22 x 1021/cm3 2.46 2.00/Ω-cm, 2.50 x 1019/cm3 2.48 75K: 6.64 mV, 150K: 12.9 mV, 300K: 25.8 mV, 400K: 34.5 mV 2.49 -28.0 kA/cm2 2.50 1.20x105 exp (-5000 x/cm) A/cm2, 12.0 mA 2.54 1.108 µm 2.57 8 atoms, 1.60x10-22 cm3, 5.00x1022 atoms/cm3, 3.73x10-23 g, 1.66x10-24 g/proton 3 Chapter 3 3.1 0.0373 µm, 0.0339 µm, 3.39 x 10-3 µm, 0.979 V, 5.24 x 105 V/cm 3.4 1018/cm3, 102/cm3, 1018/cm3, 102/cm3, 0.921 V, 0.0488 µm 3.6 6.80 V, 1.22 µm 3.10 640 kA/cm2 3.13 1.00 x 1021/cm4 3.17 290 K 3.20 312 K 3.21 1.39, 3.17 pA 3.22 0.791 V; 0.721 V; 0 A; 9.39 aA, -10.0 aA 3.25 1.34 V; 1.38 V 3.28 0.518 V; 0.633 V 3.29 335.80 K, 296.35 K 3.33 0.757 V; 0.717 V 3.35 −1.96 mV/K 3.39 0.633 V, 0.949 µm, 3.89 µm, 12.0 µm 3.40 374 V 3.42 4 V, 0 Ω 3.44 10.5 nF/cm2; 232 pF 3.46 800 fF, 20 fC; 20 pF, 0.5 pC 3.50 9.87 MHz; 15.5 MHz 3.51 0.495 V, 0.668 V 3.53 0.708 V, 0.718 V; 0.808 V 3.58 (a) Load line: (450 µA, 0.500 V); SPICE: (443 µA, 0.575 V) (b) Load line: (-667 µA, -4 V); (c) Load line: (0 µA, -3 V); 3.61 (0.600 mA, -4 V) , (0.950 mA, 0.5 V) , (-2.00 mA, -4 V) 3.68 Load line: (50 µA, 0.5 V); Mathematical model: (49.9 µA, 0.501 V); Ideal diode model: (100 µA, 0 V); CVD model: (40.0µA, 0.6 V) 3.72 (a) 0.625 mA, -5 V; 0.625 mA, +3 V; 0 A, 7 V; 0 A, -5 V 4 3.74 (c) (270 µA, 0 V), (409 µA, 0 V); (c) (0 A -3.92 V), (230 µA, 0 V) 3.76 (b) (0.990 mA, 0 V) (0 mA, -1.73 V) (1.09 mA, 0) (c) (0 A, -0.667 V) (0 A, -1.33 V) (1.21 mA, 0 V) 3.79 (1.50 mA, 0 V) (0 A, -5.00 V) (1.00 mA, 0) 3.82 (IZ, VZ) = (887 µA, 4.00 V) 3.84 12.6 mW 3.86 1.25 W, 3.50 W 3.91 17.6 V 3.95 -7.91 V, 1.05 F, 17.8 V, 3530 A, 840 A (ΔT = 0.628 ms) 3.97 (b) -7.91V, 904 µF, 17.8 V, 3540 A, 839 A 3.99 6.06 F, 8.6 V, 3.04 V, 962 A, 9280 A 3.104 -24.5 V, 1.63 F, 50.1 V, 15600 A, 2200 A 3.107 3.03 F, 8.6 V, 3.04 V, 962 A, 3770 A 3.112 2380 µF, 2800 V, 1980 V, 126 A, 2510 A 3.119 5 mA, 4.4 mA, 3.6 mA, 5.59 ns 3.123 (0.969 A, 0.777 V); 0.753 W; 1 A, 0.864 V 3.125 1.11 µm, 0.875 µm; far infrared, near infrared 5 Chapter 4 4.3 10.5 x 10-9 F/cm2 4.4 43.2 µA/V2, 86.4 µA/V2, 173 µA/V2, 346 µA/V2 4.8 (a) 4.00 mA/V2 (b) 4.00 mA/V2, 8.00 mA/V2 4.11 +840 µA; −880 µA 4.15 23.0 Ω; 50.0 Ω 4.18 125 µA/V2; 1.5 V; enhancement mode; 1.25/1 4.20 0 A, 0 A, 1.88 mA, 7.50 mA, 3.75 mA/V2 4.22 1.56 mA, saturation region; 460 µA, triode region; 0 A, cutoff 4.23 saturation; cutoff; saturation; triode; triode; triode 4.27 6.50 mS, 13.0 mS 4.30 2.48 mA; 2.25 mA 4.34 9.03 mA, 18.1 mA, 10.8 mA 4.37 1.13 mA; 1.29 mA 4.39 Triode region 4.40 99.5 µA; 199 µA; 99.5 µA; 99.5 µA 4.44 202 µA; 184 µA 4.46 5.17 V 4.51 40.0 µA; 72.0 µA; 4.41 µA; 32.8 µA 4.53 5810/1; 2330/1 4.56 235 Ω; 235 Ω 4.57 0.629 A/V2 4.58 400 µA 4.61 The transistor must be a depletion-mode device and the symbol is not correct. 4.65 (a) 6.09 x 10-8 F/cm2; 1.73 fF 4.67 17.3 pF/cm 4.69 20.7 nF 4.71 (a) 1.35 fF, 0.20 fF, 0.20 fF 4.74 50U, 0.5U, 2.5U, 1V, 0 4.77 10U, 0.5U, 25U, 1V, 0 6 4.79 432 µA/V2, 1.94 mA; 864 µA/V2, 0.972 mA 4.82 6.37 GHz, 2.55 Ghz; 637 GHz, 255 GHz 4.85 22λ x 12λ; 15.2% 4.88 12λ x 12λ; 15.2% 4.89 (350 µA, 1.7 V); triode region 4.92 (390 µA, 4.1 V); saturation region 4.95 (572 µA, 7.94 V); (688 µA, 7.52 V) 4.97 (50.3 µA, 8.43 V) ; (54.1 µA, 8.16 V) 4.102 (a) (116 µA, 4.15 V) 4.105 510 kΩ, 470 kΩ, 12 kΩ, 12 kΩ, 5/1 4.107 (124 µA, 2.36 V) 4.109 620 kΩ, 910 kΩ, 2.4 kΩ, 2.7 kΩ 4.111 (109 µA, 1.08 V); (33.5 µA, 0.933 V) 4.113 (42.6 µA, 0.957 V); (42.6 µA, 0.935 V) 4.115 8.8043x10-5 A; 8.323310-5 A 4.118 (73.1 µA, 9.37 V) 4.119 (69.7 µA, 9.49 V); (73.1 µA, 8.49 V) 4.122 (8.17 µA, 7.06 V), (6.74 µA, 7.57 V); (8.36 µA, 6.99 V), (6.89 µA, 7.52 V) 4.124 (91.5 µA, 8.70 V), (70.7 µA, 9.23 V); (97.8 µA, 8.48 V), (81.9 µA, 9.05 V) 4.125 2.25 mA; 16.0 mA; 1.61 mA 4.127 (322 µA, 3.18 V), 4.129 18.1 mA; 45.2 mA; 13.0 mA 4.131 1/3.84 4.132 (153 µA, -3.53 V) ; (195 µA, -0.347 V) 4.134 4.04 V, 10.8 mA; 43.2 mA; 24.5 mA; 98.0 mA 4.135 14.4 mA; 27.1 mA; 10.4 mA 4.137 (1.13 mA, 1.75 V) 4.138 (63.5 µA, -5.48 V) , R ≤ 130 kΩ 4.140 (55.3 µA, -7.09 V) , R ≤ 164 kΩ 4.143 22.3 kΩ  (127 µA, -5.50 V) 7 4.146 35.2 µA , R ≤ 318 kΩ 4.148 One possible design: 220 kΩ, 200 kΩ, 5.1 kΩ, 4.7 kΩ 4.149 (281 µA, -12.2 V) 4.151 (32.1 µA, -1.41 V) 4.153 (36.1 µA, 80.6 mV); (32.4 µA, -1.32 V); (28.8 µA, -2.49 V) 4.155 (431 µA, 6.47 V) 4.156 2.5 kΩ, 10 kΩ 4.157 ID = 1.38 mA, IG = 0.62 mA, VS = -0.7 V 4.159 (76.4 µA, 7.69 V), (76.4 µA, 6.55 V), 5.18 V 4.160 (a) (69.5 µA, 3.52 V) 4.162 (69.5 µA, 5.05 V); (456 µA, 6.20 V), 4.167 10.0 V; 10.0 mA, 501 mA; 13.8 V 4.169 15.0 V; 15.0 mA, 1.00 A; 12.2 V 8 Chapter 5 5.4 0.167, 0.667, 3.00, 0.909, 49.0, 0.995, 0.999, 5000 5.5 0.2 fA; 0.101 fA, −0.115 V 5.6 0.374 µA, -149.6 µA, +150 µA, 0.626 V 5.9 0.404 fA 5.11 1.45 mA; −1.45 mA 5.14 -25 µA, -100 µA, +75 µA, 65.7, 1/3, 0, 0.599 V 5.17 1.77 µA, -33.2 µA, +35 µA, 0.623 V 5.20 (a) 723 µA 5.24 0.990, 0.333, 2.02 fA, 6.00 fA 5.26 83.3, 87.5, 100 5.33 39.6 mV/dec, 49.5 mV/dec, 59.4 mV/dec, 69.3 mV/dec 5.34 5 V, 60 V, 5 V 5.35 2.31 mA; 388 µA; 0 5.36 60.7 V 5.40 Cutoff 5.42 saturation, forward-active region, reverse-active region, cutoff 5.46 25.0 aA, 1.33 aA, 26.3 aA 5.47 IC = 81.4 pA, IE = 81.4 pA, IB = 4.28 pA, forward-active region; although IC, IE, IB are all very small, the Transport model still yields IC ≅ βFIB 5.48 79.0, 6.83 fA 5.49 83.3, 1.73 fA 5.50 55.3 µA, 0.683 µA, 54.6 µA 5.51 6.67 MHz; 500 MHz 5.53 1.5, 31.1 aA 5.55 -19.9 µA, 26.5 µA, -46.4 µA 5.58 17.3 mV, 0.251 mV 5.60 1.81 A, 10.1 A 5.62 0.768 V, 0.680 V, 27.5 mV 5.65 24.2 µA 5.66 4.0 fF; 0.4 pF; 40 pF 9 5.68 750 MHz, 3.75 MHz 5.71 0.149 µm 5.72 71.7, 43.1 V 5.74 74.1, 40.0 V 5.75 100 µA, 4.52 µA, 95.5 µA, 0.651 V, 0.724 5.77 26.3 µA 5.78 (c) 33.1 mS 5.79 0.388 pF at 1 mA 5.81 (b) 38% reduction 5.83 (80.9 µA, 3.80 V) ; (405 µA, 3.80 V); (16.2 µA, 3.80 V) ; (81.9 µA, 3.72 V); 5.88 (38.8 µA, 5.24 V) 5.90 36 kΩ, 75 kΩ, 3.9 kΩ, 3 kΩ; (0.975 mA, 5.24 V) 5.93 12 kΩ, 20 kΩ, 2.4 kΩ, 1.2 kΩ; (0.870 mA, 1.85 V) 5.95 (7.5 mA, 4.3 V) 5.97 (5.0 mA, 1.3 V) 5.99 30 kΩ, 620 kΩ; 24.2 µA, 0.770 V 5.101 5.28 V 5.103 3.21 Ω 5.104 10 V, 100 mA, 98.5 mA, 10.7 V 5.105 10 V, 109 mA, 109 mA, 14.3 V 10 Chapter 6 6.1 10 µW/gate, 8 µA/gate 6.3 2.5 V, 0 V, 0 W, 62.5 µW; 3.3 V, 0 V, 0 V, 109 µW 6.5 VOL = 0 V, VOH = 2.5 V, VREF = 0.8 V; Z = A 6.7 3 V, 0 V, 2 V, 1 V, −3 6.9 2 V, 0 V, 2 V, 5 V, 3 V, 2 V 6.11 3.3 V, 0 V, 3.0 V, 0.25 V, 1.8 V, 1.5 V, 1.2 V, 1.25 V 6.13 −0.80 V, −1.35 V 6.15 1 ns 6.17 0.152 µW/gate, 22.7 aJ 6.19 2.5 µW/gate, 1.39 µA/gate, 2.5 fJ 6.20 2.20 RC; 2.20 RC 6.22 −0.78 V, −1.36 V; 9.5 ns, 9.5 ns; 4 ns, 4 ns; 4 ns 6.25 Z=01010101 6.27 Z=00010011 6.30 2;1 6.32 84.5 A 6.33 0.583 pF 6.37 3 µW/gate, 1.67 µA/gate 6.38 72 kΩ, 1/1.04 6.39 (b) 2.5 V, 5.48 mV, 15.6 µW 6.43 (a) 0.450 V, 1.57 V 6.46 (a) 0.521 V, 1.81 V 6.49 NML: 0.242 V, 0.134 V, 0.351 V; NMH: 0.941 V, 0.508 V, 1.25 V 6.51 34.1 kΩ; 1.82/1; 1.49 V, 0.266 V 6.53 81.8 kΩ, 1/1.15 6.54 250 Ω; 625 Ω; a resistive channel exists connecting the source and drain; 20/1 6.55 1.44 V 6.57 2.17 V 6.58 1.55 V, 0.20 V, 0.140 mW, 0.260 mW 11 6.62 2.5 V, 0.206 V, 0.434 mW 6.65 1.40/1, 6.67/1 6.67 (b) 2.43/1, 1/3.97 6.69 0.106 V 6.71 1.55 V, 0.20 V, 0.150 mW 6.74 -2.40 at vO = 0.883 V 6.75 -2.44 at vO = 1.08 V 6.77 3.79 V 6.79 3.3 V, 0.296 V, 1.25 mW 6.82 1.75/1, 1/8.79 6.84 1.014 6.85 1.46/1, 1.72/1 6.86 2.5 V, 0.2 V, 0.16 mW 6.89 -5.98 at vO = 1.24 V 6.90 1.80/1, 0.610 V, 0.475 V 6.91 (a) 0.165 V, 80 µA (b) 0.860 V, 0.445 V 6.93 (a) 0.224 V, 88.8 µA (b) 0.700 V, 0.449 V 6.95 1.65/1, 1/2.32, 0.300 V, 0.426 V 6.97 0.103 V, 84.5 µA 6.98 0.196 V 6.102 2.22/1, 1.81/1 6.103 2.22/1, 1.11/1, 0.0643 V 6.104 6.66/1, 1.11/1, 0.203 V, 6.43/1, 6.74/1, 7.09/1 6.107 Y = ( A + B)(C + D) E , 6.66/1, 1.11/1 6.111 Y = ACE + ACDF + BF + BDE , 3.33/1, 26.6/1, 17.8/1 ! ! 6.115 1/1.80, 3.33/1 6.117 Y = (C + E ) [A(B + D ) + G ] + F ; 3.62/1, 13.3/1, 4.44/1, 6.67/1 6.120 3.45/1, 6.43/1, 7.09/1, 6.74/1 6.122 1.11/1, 7.09/1, 6.43/1, 6.74/1 6.124 64.9 mV 12 6.126 (a) 5.43/1, 9.99/1, 6.66./1, 20.0/1 6.128 (a) 7.24/1, 26.6/1, 13.3/1 6.132 I D* = 2I D | PD* = 2PD 6.133 80 mW, 139 mW ! 6.134 1 ns 6.137 60.2 ns, a potentially stable state exists with no oscillation 6.139 31.7 ns, 4.39 ns, 5.86 ns 6.141 5.50 kΩ, 11.6/1 6.144 68,4 ns, 3.55 ns, 9.18 ns 6.146 47.1 ns, 6.14 ns, 5.39 ns 6.148 2.11/1, 16.7/1, 12.8 ns, 0.923 ns 6.149 2.68/1, 3.29/1, 884 µW 6.150 (a) 1/1.68 (d) 1/5.89 (f) 1/1.60 6.152 −1.90 V, −0.156 V 6.153 1/3.30, 1.75/1 6.154 2.30 V, 1.07 V 6.156 Y = A + B ! 13 Chapter 7 7.1 173 µA/V2 ; 69.1 µA/V2 7.3 250 pA; 450 pA; 450 pA 7.6 2.5 V, 0 V 7.8 cutoff, triode, triode, cutoff, saturation, saturation 7.11 1.25 V; 42.3 µA; 1.104 V; 25.4 µA 7.12 0.90 V; 16.0 µA; 0.810 V; 96.2 µA 7.14 1.104 V 7.15 (b) 2.5 V, 92.8 mV 7.17 1.16 V, 0.728 V 7.18 0.810 V 7.22 0.9836 V, 2.77 mA 7.23 6.10/1, 1/5.37 7.24 (a) 1.89 ns, 1.89 ns, 0.630 ns 7.27 9.47 ns, 3.97 ns, 2.21 ns 7.31 2.11/1, 5.26/1 7.33 63.2/1, 158/1 7.35 6.00/1, 15.0/1 7.38 2.76/1 7.41 1.7 ns, 2.3 ns, 1.1 ns, 0.9 ns, C = 138 fF 7.43 0.200 µW/gate; 55.6 A 7.44 1.0 µW/gate; 18.4 fF; 32.0 fF; 61.7 fF 7.46 5.00 W; 8.71 W 7.49 90.3 µA; 25.0 µA 7.52 436 fJ; 425 MHz; 926 µW 7.55 αΔT, α2P, α3PDP 7.58 SPICE: 22.3 ns, 24.2 ns, 16.3 ns, 18.3 ns; Propagation delay formulas: 7.6 ns, 6.9 ns 7.59 2/1, 20/1; 6/1, 60/1 7.61 1/3.75 7.63 1.25/1 14 7.70 3.95 ns, 3.95 ns, 11.8 ns 7.71 4.67/1; 7.5/1 7.72 5 transistors; The CMOS design requires 47% less area. 7.74 Y = ( A + B)(C + D) E = ACE + ADE + BDE + BCE ; 12/1, 20/1, 10/1; 2.4/1; 30/1 7.76 Y = A + B C + D E + F = AB + CD + EF ; 4/1, 15/1; 6/1; 10/1 ! 7.78 ! ( )( )( ) 2/1, 4/1, 6/1, 20/1 7.81 (a) Path through NMOS A-D-E (d) Paths through PMOS A-C and B-E 7.83 24/1, 20/1, 40/1 7.84 6/1, 4/1, 10/1 7.91 5.37 ns, 1.26 ns 7.93 1.26 ns, 0.737 ns, 4.74 ns, 4.16 ns 7.95 4.74 ns, 2.37 ns 7.103 VDD ! 2 1 2VIH 2VIH V ! VDD ; R " = , C1 ≥ 83.1C2 3 DD 2 VDD # VIH N MH 7.109 8; 2.90; 23.2 Ao 7.112 Ao " N #1 " #1 7.113 263 Ω; 658 Ω ! 7.116 240/1, 96.2/1 7.117 1.41 V, 2.50 V 7.119 Latchup does not occur. 7.122 +0.25; +0.31 7.124 211,000/1; 0.0106 cm2 15 Chapter 8 8.1 268,435,456 bits, 1,073,741,824 bits; 2048 blocks 8.2 3.73 pA/cell , 233 fA/cell 8.5 3 V, 0.667 µV 8.9 1.55 V, 0 V, 3.59 V 8.11 “1” level is discharged by junction leakage current 8.13 1.47 V, 1.43 V 8.14 −19.8 mV; 2.48 V 8.16 0 V, 1.90; Junction leakage will destroy the “1” level 8.18 5.00 V, 1.60 V; −1.84 V 8.22 135 µA, 346 mW 8.24 0.266 V 8.25 0.945 V (The sense amplifier provides a gain of 10.5.) 8.31 0 V, 1.43 V, 3.00 V 8.32 0.8 V, 1.2 V; 0.95 V, 0.95 V 8.34 53,296 8.37 VDD ! 8.41 W1 = 010001102 , W3 = 001010112 8.45 1.16/1 2 1 2VIH 2VIH V ! VDD ; R " = ; C1 ≥ 2.88C2 3 DD 2 VDD # VIH N MH 16 Chapter 9 ! 9.1 0 V, -0.700 V 9.2 (a) -1.38 V, -1.12 9.3 −1.50 V, 0 V 9.6 0 V, −0.40 V; 3.39 kΩ; Saturation, cutoff; Cutoff, saturation 9.8 −0.70 V, −1.30 V, −1.00 V, 0.60 V 9.11 −0.70 V, −1.50 V, −1.10 V, 2.67 kΩ; 0.289 V; −0.10 V, +0.30 V 9.13 -1.70 V, -2.30 V, 0.60 V, Yes 9.15 11 9.16 11.1 kΩ, 12.0 kΩ, 70.2 kΩ, 252 kΩ 9.18 -1.10 V, -1.50 V, -1.30 V, 0.400 V, 0.107 V, 1.10 mW 9.19 0.383 V 9.21 -0.70 V, -1.50 V, -1.10 V, 11.3 kΩ, 2.67 kΩ, 2.38 kΩ; 0.289 V 9.23 0.413 V 9.25 50.0 µA, -2.30 V 9.26 Standard values: 11 kΩ, 150 kΩ, 136 kΩ 9.30 +0.300 V, −0.535 V, 334 Ω 9.33 5.15 mA 9.36 0.135 mA 9.38 10.7 mA 9.40 400 Ω, 75.0 mA 9.42 (c) 0 V, -0.7 V, 3.93 mA (d) -3.7 V, 0.982 mA (e) 2920 Ω 9.45 Y = A+ B 9.47 −0.850 V; 3.59 pJ 9.49 359 ns 9.50 0 V, −0.600 V, 5.67 mW, 505 Ω, 600 Ω; Y = A + B + C, 5 vs. 6 9.53 5.00 kΩ, 5.40 kΩ, 31.6 kΩ, 113 kΩ 9.54 1 kΩ, 1 kΩ, 1.30 mW 9.56 2.23 kΩ, 4.84 kΩ, 60.1 kΩ 9.59 1.446 mA, 1.476 mA, 29.66 µA; 1.446 mA, 1.476 mA, 29.52 µA 17 ! 9.61 -0.9 V, -1.1 V, -1.8 V, -2.0 V, -2.7 V, -2.9 V, -4.2 V 9.64 Y = AB + AC 9.68 0, -0.8. 0, -0.8, 3.8 V 9.69 2.98 pA, 70.5 fA 9.71 160; 0.976; 0.976; 0.773 V 9.72 0.691 V, 0.710 V 9.76 63.3 µA, 265 µA 9.78 40.2 mV, 0.617 mV 9.80 20.6 mW, 4.22 mW 9.82 68.2 mV 9.83 2.5 V, 0.15 V, 0.66 V, 0.80 V 9.85 44.8 kΩ, 22.4 kΩ 9.88 5 V, 0.15 V, 0, −1.06 mA; 31; −1.06 mA vs. −1.01 mA, 0 mA vs. 0.2 mA 9.95 8 9.97 RB ≥ 5 kΩ 9.99 7 9.100 234 mA, 34.9 mA 9.104 (IB, IC): (a) (135 µA, −169µA); (515µA, 0); (169 µA, 506 µA); (0, 0) (b) all 0 except IB1 = IE1 = 203 µA 9.107 180 9.108 22 9.111 1.85 V, 0.15 V; 62.5 µA, −650 µA; 13 9.113 Y = ABC ; 1.9 V; 0.15 V; 0, −408 µA 9.115 1.5 V, 0.25 V; 0, −1.00 mA; 16 9.116 0.7 V, 191 µA, 59 µA, 1.18 mA 9.117 -1.13 mA, 0, 4.50 mA, 0, 0, 1.80 mA; 0, 0, 0, 0, 1.23 mA, 0 9.119 Y = A + B + C; 0 V, −0.8 V; −0.40 V 9.121 1.05 mA, 26.9 µA 9.122 2 fJ; 10 fJ 9.124 1.67 ns; 0.5 mW 9.126 2.8 ns; 140 mW 18 Chapter 10 10.2 (a) 41.6 dB, 35.6 dB, 94.0 dB, 100 dB, -0.915 dB 10.4 29.35 10.5 Using MATLAB: t = linspace(0,.004); vs = sin(1000*pi*t)+0.333*sin(3000*pi*t)+0.200*sin(5000*pi*t); vo= 2*sin(1000*pi*t+pi/6)+sin(3000*pi*t+pi/6)+sin(5000*pi*t+pi/6); plot(t,vs,t,vo)par 500 Hz: 1 0°, 1500 Hz: 0.333 0°, 2500 Hz: 0.200 0°; 2 30°, 1 30°, 1 30° 2 30°, 3 30°, 5 30° yes 10.7 29.0 dB, 105 dB, 67.0 dB 10.9 19.0 dB, 87.0 dB, 53.0 dB; Vo = 8.94 V, recommend ±10-V or ±12-V supplies 10.11 3.61 x10-8 S, -7.93 x10-3, 1.00, 79.3 Ω 10.13 0.333 mS, -0.333, -1600, 1.78 MΩ 10.15 1.00 mS, −1.00, 3001, 30.0 kΩ 10.16 53.7 dB, 150 dB, 102 dB; 11.7 mV; 31.3 mW 10.17 45.3 mV, 1.00 W 10.21 −5440 10.23 0, ∞, 80 mW, ∞ 10.24 182 10.29 −10 (20 dB), 0.1 V; 0, 0 V 10.31 vO = [8 – 4 sin (1000t)] volts; there are only two components; dc: 8 V, 159 Hz: −4 V 10.33 24.1 dB, 2nd and 3rd, 22.4% 10.35 2.4588 0.0012 0.0038 5.3105 0.1863 0.0023 0.0066 1.3341 10.37 59.7 dB, 119 dB, 88.9 dB; 5.66 mV 10.41 Rid ≥ 4.95 MΩ 10.43 50 µV, 140 dB 10.44 (a) −46.8, 4.7 kΩ, 0, 33.4 dB 10.47 (d) (-1.10 + 0.75 sin 2500πt) V 10.49 (a) vO = (4.00 " 20Vi sin 2000#t ) V (b) 0.3 V 10.53 30.1 kΩ, 604 kΩ Av = -20.1, Rin = 30.1 kΩ ! 10.56 -70.0, 10 kΩ, 0 19 0.0026 0.4427 0.0028 0.0883 10.59 2 MΩ 10.60 83.9, ∞, 0, 38.5 dB 10.63 (d) (5.28 – 2.88 sin 3250πt) V 10.67 2 kΩ, 86.6 kΩ, Av = 44.3 10.69 (-0.47 sin 3770t −0.94 sin 10000t) V, 0 V 10.70 −0.3750 sin 4000πt V; −0.6875 sin 4000πt V; 0 to −0.9375 V in - 62.5-mV steps 10.71 455/1, 50/1 10.72 −10, 110 kΩ, 10 kΩ, (-30 + 15cos 8300πt) V, (-30 + 30cos 8300πt) V 10.73 3.2 V, 3.1 V, 2.82 V, 2.82 V, -1.00 V; 3.82 µA; 3.80 µA, 2.80 µA 10.76 60 dB, 10 kHz, 10 Hz, 9.99 kHz, band-pass amplifier 10.77 80 dB, ∞, 100 Hz, ∞, high-pass amplifier 10.81 60 dB, 100 kHz, 28.3 Hz, 100 kHz 10.83 Using MATLAB: n=[1e4 0]; d=[1 200*pi]; bode(n,d) 10.86 Using MATLAB: n=[-20 0 -2e13]; d=[1 1e4 1e12]; bode(n,d) 10.89 0.030 sin (2πt + 89.4°) V, 1.34 sin (100πt + 63.4°) V, 3.00 sin (104πt + 1.15°) V 10.92 0.956 sin (3.18x105πt + 101°) V, 5.00 sin (105πt + 180°) V, 5.00 sin (4x105πt − 179°) V 10.94 Av ( s) = 2x108 " s + 10 7 " | Av ( s) = - 2x108 " s + 10 7 " 10.96 66 dB, 12.8 kHz, -60 dB/decade 10.97 3.16 sin (1000πt + 10°) + 1.05 sin (3000πt + 30°)+ 0.632 sin (5000πt + 50°) V ! Using MATLAB: t = linspace(0,.004); A=10^(10/20); vs = sin(1000*pi*t)+0.333*sin(3000*pi*t)+0.200*sin(5000*pi*t); vo = A*sin(1000*pi*t+pi/18)+3.33*sin(3000*pi*t+3*pi/18)+2.00*sin(5000*pi*t+5*pi/18); plot(t, A*vs, t, vo) 10.98 -4.44 dB, 26.5 kHz 10.100 10 kΩ, 0.015 µF 10.103 80 dB, 100 Hz 10.105 -1.05 dB, 181 Hz 10.107 (b) -20.7, 105 kHz 10.108 10.5 kΩ, 105 kΩ, 0.015 µF 20 10.113 T(s) = -sRC 10.116 −6.00, 20.0 kΩ, 0; +9.00, 91.0 kΩ, 0; 0, 160 kΩ, 0 10.117 1 A, 2.83 V, > 10 W (choose 15 W) 10.118 0.484 A; 0.730 V; 0.730 V; ≥ 7.03 W (choose 10 W), 7.27 W 21 Chapter 11 11.1 (c) 4, 5.00, 4.00, 20 % 11.3 120 dB 11.4 1/(1+Aβ); 9.99! 10"3percent 11.5 (a) 13.49, 9.11x10-3, 0.0675% 11.7 120 dB 11.9 (a) -9.997, 2.76x10-3, 0.0276% 11.13 103 dB 11.16 100 µA, 100 µA, -48.0 pA, +48.0 pA 11.17 (a) 13.5, 296 MΩ, 135 mΩ 11.19 (a) -17.4, 2.70 kΩ, 36.8 mΩ 11.22 If the gain specification is met with a non-inverting amplifier, the input and output specifications cannot be met. 11.24 145Vs, 3.56 Ω 11.25 ≤ 0.75 % 11.27 (b) shunt-series feedback (d) series-shunt feedback 11.29 (a) Series-shunt (a) and series-series (c) feedback 11.32 122 dB, 31.5 S 11.33 9.96, 6.55 MΩ, 3.19 Ω 11.35 9130, 3.00, 3.00, 369 MΩ, 0.398 Ω 11.37 (c) -T/(1+T) 11.39 -9.998 kΩ, 1.200 Ω, 0.1500 Ω 11.41 -35.99 kΩ, 4.418 Ω, 0.2799 Ω 11.44 -99.91 µS, 50.04 MΩ, 17.79 MΩ 11.49 10000s ( s + 5000) , 10000 (2s + 1) 11.54 1.100, 1.899 Ω, 24.65 MΩ ! 11.56 10.96, 35.12 Ω, 3.461 MΩ 11.57 680.4, 0.334 11.59 330, 0.0260 11.61 6.25 %, 16.7 % 22 11.62 0.00372 %, 0.0183 % 11.63 0 V, -26 mV, 90.9 kΩ 11.65 +7500, -0.667 mV 11.68 The nearest 5% values are 1 MΩ and 10 kΩ 11.70 -6.2 V, 0 V; 10 V, -1.19 V 11.72 -5.00 V, 0 V; -10.0 V, 0.182 V 11.74 10 V, 0 V; 15 V, 0.125 V 11.77 110 Ω and 22 kΩ represent the smallest acceptable resistor pair. 11.79 39.2 Ω 11.81 0 V, 3 V; 0.105 V; 0 V; 49.0 dB 11.83 (d) [-0.313 sin 120πt - 4.91 sin 5000πt] V 11.85 (b) 124 dB 11.86 60 dB 11.87 20.0 kΩ, 56.0 kΩ 11.89 20 Hz 11.91 50 Hz; 5 MHz; 2.5 MHz 11.93 200; 199 11.95 80 dB, 1 kHz, 1 MHz; 101 MHz, 9.90 Hz; 251 MHz, 3.98 Hz 11.97 100 dB, 1 kHz, 1 MHz; 8.4 Hz, 119 MHz; 5.3 Hz, 188 MHz [ ] 11.99 (a) Ro ( s + " B ) s + " B (1+ Ao# ) [ ] (s + " ) 11.102 (a) Rid s + " B (1+ Ao# ) ! 11.105 Av ( s) = " ! 11.107 3.285x1012 ; (2 poles: 2.08 kHz and 2.04 MHz) s2 + 1.284x10 7 s + 1.675x1011 Av ( s) = " 6.283x1010 ; (2 poles: 3.18 mHz and 5.00 MHz) s2 + 3.142x10 7 s + 6.283x105 ! B 11.109 ! 11.111 6.91, 7.53, 6.35; 145 kHz, 157 kHz, 133 kHz 11.113 10 V/µs 11.117 1010 Ω, 7.96 pF, 4x106, Ro not specified 2.51 V/µs; 2.51 V/ s 23 11.119 90.6 o; 90.2o 11.120 8.1 o; 5.1o 11.122 110 kHz; A ≤ 2048; larger 11.123 Yes, but almost no phase margin; 0.4° 11.125 75 o versus 90o; 65 o versus 90o 11.128 5 MHz, 90.0o; 2.5 MHz, 90.0o 11.130 Av ( s) = " 11.132 Yes, but almost no phase margin; 1.83° 11.134 ! 11.136 90.0o 11.141 Yes, 24.4o, 50 % 11.143 1.8o 11.144 38.4o, 31 % 11.147 133 pF 11.149 90.4o 11.152 (a) 72.2o 11.153 (a) 11.9 MHz, 5.73o, 85.4% 11.155 (a) 70.2, 23.4% 11.157 (a) 18.8 MHz 5.712x106 s ; 143o 2 5 10 s + 5.741x10 s + 1.763x10 12o; Yes, 50o 24 Chapter 12 12.1 A and B taken together, B and C taken together 12.3 -8000, 2 kΩ, 0 12.5 48.0, 968 MΩ, 46.5 mΩ 12.7 78.1 dB, 2.00 kΩ, 0.105 Ω 12.8 (c) 2.00 mV, -40.0 mV, 4.00 µV, 0.800 V, 80.0 µV, 0 V, -12.0 V, 0.190 V, 0V (ground node) 12.11 -1080, 3.9 kΩ, 0 12.12 8.62 kΩ, 8.62 kΩ 12.16 2744, 2434, 3094, 1 MΩ, 1.02 MΩ, 980 kΩ, 0 12.17 -1320, 75 kΩ, 0; 5.00 mV, 5.00 mV, 55.0 mV, 0 V, -1.10 V, -1.10 V, -6.60 V, 0V (ground node) 12.19 50.0, 298 kHz; 48.0, 349 kHz; -42.0, 368 kHz 12.21 14.0, 286 kHz, 68.8 dB, 146 kHz 12.23 -2380, 613 MΩ, 98.0 mΩ, 29.6 kHz; 0 V, 10.0 mV, 49.0 mV, 389 µV, -3.89 V, -3.06 V, -15.0 V, +15.0 V, -15.0 V, 0 V 12.25 3 12.27 20 kΩ, 62 kΩ, 394 kHz 12.30 103 dB, 98.5 dB, 65 kHz, 38 kHz 12.33 (a) In a simulation of 5000 cases, 33.5% of the amplifiers failed to meet one of the specifications. (b) 1.5% tolerance. 12.36 -12, (-6.00 + 1.20 sin 4000πt) V 12.38 4.500 V, 4.99 V, 5.01 V, 5.500 V, 2.7473 V, 2.7473 V, 0.991 V, -75.4 µA, -375 µA, +175 µA, 0.002, -50.0, 88 dB 12.40 (b) 0.005 µF, 0.0025 µF, 1.13 kΩ 12.44 VO K = 2 VS s R1 R2C1C2 + s R1C1 (1" K ) + C2 ( R1 + R2 ) + 1 [ ] 12.46 -1 ! 12.48 270 pF, 270 pF, 23.2 kΩ 12.49 (a) 51.2 kHz, 7.07, 7.24 kHz 25 | SKQ = K 3" K # &2 % "6s ( 12.52 (a) 1 rad/s, 4.65, 0.215 rad/s; ABP ( s) = % ( % s2 + s + 1( $ 3 ' 12.54 5.48 kHz, 4.09, 1.34 kHz 12.56 10 kΩ, 100 kΩ, 20 kΩ, 0.0133 µF ! s R2C2 12.58 T = + K " % 1 1 1 2 $ '+ s +s + $ R2C2 R1 R2 C1 '& R1 R2C1C2 # ( ) 12.64 -5.5 V, -5.5, 10 %; -5.0 V, -5.0, 0 ! 12.66 12.6 kHz, 1.58, 7.97 kHz 12.69 (a) -1-125 V (b) -1.688 V 12.70 10.6 mV, 5 % 12.73 455/1, 50/1 12.74 0.31 LSB, 0.16 LSB 12.76 1.43%, 2.5%, 5%, 10% 12.77 11 resistors, 1024:1 12.79 (a) 1.0742 kΩ, 0.188 LSB, 0.094 LSB 12.81 (a) (2n+1-1)C 12.84 (b) 2.02 inches 12.85 3.415469 V ≤ VX ≤ 3.415781 V 12.86 1.90735 µV, 110100001010001111012, 011111111001110111012 12.89 00010111112, 95 µs 12.91 800 kHz, 125 ns 12.93 # & "t vO (t ) = 2.5x105 %1" exp ( for t ) 0 | RC ) 0.0447 s 5x10 4 RC ' $ 12.94 19.1 ns ! 12.97 1/RC, 2R 12.98 0.5774/RC, 1.83 12.100 60 kHz, 6.8 V 26 12.102 17.5 kHz, 11.5 V 12.106 0.759 V 12.107 2.4 Hz 12.112 VO = -V1V2/104IS 12.113 3.11 V, 2.83 V, 0.28 V 12.115 0.445 V, -0.445 V, 0.89 V 12.117 9.86 kHz 12.118 VO = 0 is a stable state, so the circuit does not oscillate. f = 0. 12.120 0, 0.298 V, 69.0 mV 12.122 13 kΩ, 30 kΩ, 51 kΩ, 150 pF 27 Chapter 13 13.1 (0.700 + 0.005 sin 2000πt) V, -1.03 sin 2000πt V, (5.00 −1.03 sin 2000πt) V. 2.82 mA 13.3 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the collector to the output vO. C3 is a bypass capacitor. (b) The signal voltage at the top of resistor R4 will be zero. 13.5 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. (b) The signal voltage at the source of M1 will be vs = 0. 13.7 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the collector to output vO. (b) The signal voltage at the emitter terminal will be ve = 0. 13.9 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a coupling capacitor that couples the ac component of the signal at the drain to output vO. 13.13 (a) C1 is a coupling capacitor that couples the ac component of vI into the amplifier. C2 is a bypass capacitor. C3 is a coupling capacitor that couples the ac component of the signal at the drain to the output vO. (b) The signal voltage at the top of R4 will be zero. 13.16 (1.46 mA, 5.36 V) 13.18 (19.2 µA, 6.37 V) 13.20 (62.2 µA, 43.65 V) 13.24 (91.3 µA, 6.05 V) 13.28 (245 µA, 3.73 V) 13.32 (423 µA, -6.76 V) 13.34 (1.25 mA, 8.63 V) 13.46 Thévenin equivalent source resistance, gate-bias voltage divider, gate-bias voltage divider, source-bias resistor—sets source current, drain-bias resistor—sets drainsource voltage, load resistor 13.51 118 Ω, 3.13 TΩ, ≤ -28.5 mV 13.52 (c) 8.65 Ω 13.53 Errors: +10.7%, -9.37%; +23.0%, - 17.5% 28 13.54 (c) 1.25 µA 13.55 (213 µA, ≥ 0.7 V), 8.52 mS, 469 kΩ 13.60 (b) +16.7%, -13.6% 13.61 90, 120; 95, 75 13.66 [−76.7, −75.8] 13.68 -40.0 13.72 −90 13.74 Yes, using ICRC = (VCC +VEE)/2 13.76 3 13.77 20 mA; 24.7 V 13.78 0.500 V 13.79 No, there will be significant distortion 13.80 −263 13.85 32/1, 0.500 V 13.86 0.800 A 13.87 10%, 20% 13.90 (78 µA, 9 V) 13.91 Virtually any desired Q-point 13.92 400 = 133,000iP + vPK; (1.4 mA, 215 V); 1.6 mS, 55.6 kΩ, 89.0; -62.7 13.93 FET 13.94 BJT 13.95 37.5 µA, 2400 13.96 2000, 200, 8.00 mS, 0.800 mS 13.99 23.5 dB 13.101 (142 µA, 7.5 V) 13.102 0.300 V 13.103 1.0 V, 56 V 13.105 3 13.107 −11.0 13.110 −7.28 29 13.115 29.4 kΩ, 93.4 kΩ 13.118 833 kΩ, 1.46 MΩ 13.120 243 kΩ, 40.1 kΩ 13.122 6.8 MΩ, 45.8 kΩ, independent of Kn 13.124 1 MΩ, 3.53 kΩ 13.125 -281vi, 3.74 kΩ 13.127 -23.6vi, 508 kΩ 13.129 38.9 dB, 6.29 kΩ, 9.57 Ω 13.131 36.4 dB, 62.9 kΩ, 95.7 kΩ 13.135 138 µW, 182 µW, 1.28 mW, 0.780 mW, 0.820 mW, 3.19 mW 13.139 0.552 mW, 0.684 mW, 0.225 mW, 18.7 µW, 50.4 µW, 1.53 mW 13.142 VCC/15 13.143 3.38 V, 13.6 V 13.144 (VCC)2/8RL, (VCC)2/2RL, 25% 13.145 0.992 V 13.147 2.24 V 13.148 1.65 V 13.149 2.93 V 13.153 833 µA 13.154 -4.60, 1 MΩ, 6.82 kΩ 30 Chapter 14 14.1 (a) C-C or emitter-follower (c) C-E (e) not useful, signal is being injected into the drain (h) C-B (k) C-G (o) C-D or source-follower 14.14 −32.6, 9.58 kΩ, 596 kΩ, -27.1; −17.2, 11.6 kΩ, 1060 kΩ, -17.1 14.15 −3.77, 2 MΩ, 26.5 kΩ, -3770; −8.03, 2 MΩ, 10.0 kΩ, -10000 14.16 (a) −6.91 (e) −240 14.17 3.3 kΩ, 33 kΩ 14.20 −178, - 58, 21.4 kΩ, 39 kΩ, 5.13 mV 14.21 121, - 62, 2.84 kΩ, 7.58 kΩ, 6.76 mV, -120 14.22 −12.3, −9.62, 368 kΩ, 82 kΩ, 141 mV, -7.50 14.24 -2.74, -762, 10 MΩ, 1.80 kΩ, 0.800 V 14.25 -3790, -5.44, 1.30 kΩ, 68.5 kΩ, 5.96 mV 14.27 0.747, 29.8 kΩ, 104 Ω, 29.7 14.28 0.896, 2 MΩ, 125 Ω, 16,000 14.29 0.987, 44.8 kΩ, 15.2 Ω, 1.54 V 14.30 0.960, 1 MΩ, 507 Ω, 6.19 V 14.31 0.992, 12.6 MΩ, 1.32 kΩ, 0.601 V 14.32  , 7.94 MΩ, 247 Ω, ∞ 14.33 vi " (0.005 + 0.2VR E ) V 14.35 0.9992, 30.1 V ! 14.37 190, 980 Ω, 2.52 MΩ, 0.990; 62.1, 980 Ω, 7.57 MΩ, 0.969 14.38 39.4, 1.20 kΩ, ∞, 0.600; 7.94, 1.43 kΩ, ∞, 0.714 14.41 40.7, 185 Ω, 39.0 kΩ, 18.5 mV 14.42 4.11, 1.32 kΩ, 20 kΩ, 354 mV 14.43 5.01, 3.02 kΩ, 24 kΩ, 352 mV 14.46 32.1 Ω, 260 Ω 14.47 633 Ω, 353 Ω 14.49 (" o + 1)ro = 244 M# ! 31 14.51 Low Rin, high gain: Either a common-base amplifier operating at a current of 71.4 µA or a common-emitter amplifier operating at a current of approximately 7.14 mA can meet the specifications with VCC ≈ 14 V. 14.53 Large Rin, moderate gain: Common-source amplifier. 14.55 Common-drain amplifier. 14.56 Low Rin, high gain: Common-emitter amplifier with 5-Ω input "swamping" resistor. 14.57 Cannot be achieved with what we know at this stage in the text. 14.59 1.66 Ω 14.62 vi 5 mV 10 mV 15 mV 1 kHz 621 mV 1.23 V 1.81 V 2 kHz 3 kHz 26.4 mV (4.2%) 0.71 mV (0.11%) 0.104 V (8.5%) 5.5 mV (0.45%) 0.228 V (12.6%) 18.2 mV (1.0%) THD 4.2% 8.5% 12.7% 14.64 (b) 479vi, 384 kΩ 14.65 vi, 297 Ω 14.68 g m , 0; 400 µS, 0 ! # 1 14.70 "g m %%1+ $ µf 14.71 " ! gm 1+ g m RE & (( | " g o ' | " | µ f + 1 ; " 502 µS, " 2.00 µS $ RE ' $ go Gm r ' = µ f &1+ # ) >> 1 & ) | (1+ g m RE ) % RE + r# ( Gr % RE ( 14.74 -0.984, 0.993, 0.766 V ! 14.76 SPICE: (116 µA, 7.53 V), −150, 19.6 kΩ, 37.0 kΩ 14.78 SPICE: (115 µA, 6.30 V), -20.5, 368 kΩ, 65.1 kΩ 14.80 SPICE: (66.7 µA, 4.47 V), −16.8, 1.10 MΩ, 81.0 kΩ 14.83 SPICE: (5.59 mA, -5.93 V), -3.27, 10.0 MΩ, 1.52 kΩ 14.85 SPICE: (6.20 mA, 12.0 V), 0.953, 2.00 MΩ, 388 Ω 14.86 SPICE: (175 µA, 4.29 V), -4.49, 500 kΩ, 17.0 kΩ 14.87 (430 µA, 1.97 V), (430 µA, 3.03 V), -2.89, 257 kΩ, 3.22 kΩ, (Note Atr = 743 kΩ) 14.88 (4.50 mΑ, 2.50 V), (4.50 mA, 2.50 V), -83.5, 6.63 kΩ, 10.3 kΩ, 14.89 0.485, 182 kΩ, 435 Ω 14.92 1.80 µF, 0.068 µF, 120 µF; 2.7 µF 32 14.94 0.20 µF, 270 F; 100 µF, 0.15 µF 14.96 1.5 µF, 0.027 µF 14.98 8200 pF, 820 pF 14.102 33.3 mA 14.103 R1 = 120 kΩ, R2 = 110 kΩ 14.106 45.1 ≤ Av ≤ 55.3 - Only slightly beyond the limits in the Monte Carlo results. 14.108 The second MOSFET 14.111 The supply voltage is not sufficient - transistor will be saturated. 14.113 4.08, 1.00 MΩ, 64.3 Ω 14.116 2.17, 1.00 MΩ, 64.3 Ω 14.121 468, 73.6 kΩ, 18.8 kΩ 14.122 0.670, 107 kΩ, 20.0 kΩ 14.124 7920, 10.0 kΩ, 18.8 kΩ 14.125 140, 94.7 Ω, 113 Ω 14.127 19.2 Hz; 18.0 Hz 14.129 1.56 Hz; 1.22 Hz 14.131 6.40 Hz; 5.72 Hz 14.133 0.497 Hz, 0.427 Hz 14.134 1.70 kHz; 1.68 kHz 33 Chapter 15 15.1 (26.2 µA, 7.08 V); −346, 191 kΩ, 660 kΩ; −0.604, 49.2 dB, 27.3 MΩ 15.2 (5.25 µA, 1.68 V); −21.0, -0.636, 24.4 dB, 572 kΩ, 4.72 MΩ, 200 kΩ, 50.0 kΩ 15.4 (85.6 µA, 10.1 V); −342, -0.494, 50.8 dB, 58.4 kΩ, 10.1 MΩ, 200 kΩ, 50.0 kΩ 15.7 REE = 1.1 MΩ, RC = 1.0 MΩ 15.8 (a) (198 µA, 3.39 V); differential output: −372, 0, ∞ (b) single-ended output: −186, −0.0862, 66.7 dB; 25.2 kΩ, 27.3 MΩ, 94.0 kΩ, 13.5 kΩ 15.9 2.478 V, 6.258 V, -2.78 V, 4.64 V 15.11 VO = 5.99 V, vo = 0; VO = 5.99 V; vo = 1.80 V; 33.3 mV 15.15 (37.4 µA, 5.22 V); Differential output: −300, 0, ∞; single-ended output: −150, −0.661, 47.2 dB; 200 kΩ, 22.7 MΩ 15.16 -5.850 V, -3.450 V, -2.40 V 15.18 (4.94 µA, 1.77 V); differential output: −77.2, 0, ∞; single-ended output: −38.6, −0.0385, 60.0 dB; 810 kΩ, 405 MΩ, [-1.07 V, 1.60 V] 15.21 -283, -.00494, 95.2 dB 15.22 -273.6, -.004429, 94.9 dB 15.24 (107 µA, 10.1 V); differential output: −18.2, 0, ∞; single-ended output: −9.10, −0.487, 25.4 dB; ∞, ∞ 15.27 2.4 kΩ, 5.6 kΩ 15.31 (150 µA, 5.62 V); differential output: −26.0, 0, ∞; single-ended output: −13.0, −0.232, 35.0 dB; ∞, ∞ 15.34 (20.0 µA, 9.05 V); differential output: −38.0, 0, ∞; single-ended output: −19.0, −0.120, 44.0 dB; ∞, ∞ 15.35 312 µA, 27 kΩ 15.38 -20.26, -0.7812, 22.3 dB , ∞, ∞ 15.40 −3.80 V, −2.64 V, 48.3 mV 15.44 -79.9, -0.494, 751 kΩ 15.45 (99.0 µA, 8.80 V), −30.4, −0.167, 550 kΩ 15.47 (49.5 µA, 3.29 V), (49.5 µA, 8.70 V); −149, -0.0625, 101 kΩ 15.48 (100 µA, 1.20 V), (100 µA, 3.18 V); −13.4, 0, ∞ 15.51 (24.8 µA, 15.0 V), (625 µA, 15.0 V); 896, 202 kΩ; 20.0 kΩ; 153 MΩ; v2 15.52 [-13.6 V, 14.3 V] 34 15.57 (24.8 µA, 14.3 V), (4.95 µA, 14.3 V), (495 µA, 15.0 V); 5010, 202 kΩ; 19.4 kΩ; 150 MΩ; v2 15.58 (98.8 µA, 17.1 V), (360 µA, 17.1 V); 620, 40.5 kΩ; 48.8 kΩ; 37.5 MΩ; v2 15.59 [-16.6 V, 16.4 V] 15.63 (98.8 µA, 15.3 V), (300 µA, 15.3 V); 27700, 40.5 kΩ; 2.59 MΩ 15.67 (250 µA, 18.6 V), (500 µA, 18.0 V); 4490, ∞; 170 kΩ 15.69 5770 15.71 (250 µA, 7.42 V), (6.10 µA, 4.30 V), (494 µA, 5.00 V); 4230, ∞; 97.5 kΩ 15.75 (49.5 µA, 18.0 V), (360 µA, 17.3 V), (990 µA, 18.0 V); 12700, 101 kΩ; 1.88 kΩ; 69.2 MΩ; v2 15.77 (300 µA, 5.10 V), (500 µA, 2.89 V), (2.00 mA, 5.00 V); 528, ∞, 341 Ω 15.79 (300 µA, 5.55 V), (500 µA, 2.89 V), (2.00 mA, 5.00 V), 2930, ∞, 341 Ω 15.81 (250 µA, 10.9 V), (2.00 mA, 9.84 V), (5.00 mA, 12.0 V); 868, ∞; 127 Ω 15.82 (99.0 µA, 4.96 V), (99.0 µA, 5.00 V), (500 µA, 3.41V), (2.00 mA, 5.00 V); 11400, 50.5 kΩ, 224 Ω 15.84 (49.5 µA, 11.0 V), (98.0 µA, 10.3 V), (735 µA, 16.0 V); 2680, 101 kΩ, 3.05 kΩ  d for an ideal current source, 10.3 V]; 1.44 mV 15.86 No, Rid must be reduced or Rout must be increased. 15.88 (24.8 µA, 17.3 V), (24.8 µA, 17.3 V), (9.62 µA, 15.9 V), (490 µA, 16.6 V), (49.0 µA, 17.3 V), (4.95 mA, 18.0 V); 88.5 dB, 202 kΩ, 22.0 Ω 15.90 250 µA/V2; 280; 868 15.92 196; 896 15.94 0.9996, 239 MΩ, 21.2 Ω 15.96 9.992, 67.6 MΩ, 1.48 Ω 15.98 36.8 µA 15.101 391 µA 15.104 22.8 µA 15.106 5 mA, 0 mA, 10 mA, 12.5 percent 15.107 66.7 percent 15.110 46.7 mA, 13.5 V 15.112 23.5 µA 35 15.113 6.98 mA, 0 mA 15.114 25.0 mΩ 15.116 (a) 18.7 µA, 61.5 MΩ 15.118 (a) 134 µA, 8.19 MΩ 15.120 Two of many: 75 kΩ, 6.2 kΩ, 150 Ω; 68 kΩ, 12 kΩ, 1 kΩ 15.122 59.4 µA, 15.7 MΩ 15.123 0, ∞ 15.125 88.6 µA, 18.6 MΩ 15.127 17.0 µA, 131 MΩ 15.130 390 kΩ, 210 kΩ, 33 kΩ 15.132 157.4 µA, 16.61 MΩ, 31.89 µA, 112.2 MΩ 15.133 44.1 µA, 22.1 MΩ, 10.1 µA, 209 MΩ 15.136 400 µA, 2.89 x 1011 Ω 15.137 (4.64 µA, 7.13 V), (9.38 µA, 9.02 V); 40.9 dB, 96.5 dB 15.140 ! o1µ f1 /2 , For typical numbers: 20(100)(70) = 140,000 or 103 dB 15.141 3σ limits: IO = 199 µA ± 32.5 µA, ROUT = 11.8 MΩ ± 2.6 MΩ 3σ limits: IO = 201 µA ± 34.7 µA, ROUT = 21.7 MΩ ± 3.6 MΩ 36 Chapter 16 16.1 [4.28 kΩ, 4.50 kΩ] 16.2 2.50 mV; 5.02 mV; 1% 16.4 7.7%, 0.813 µA, 0.855 µA, (IOS = -42.0 nA) 16.7 25.0 mV; 1.2%; 0.4% 16.8 (a) 94.8 µA, 186 µA, 386 µA, 1.16 MΩ, 580 kΩ, 290 kΩ 16.11 87.5 µA, 175 µA, 350 µA; 0.0834 LSB, 0.126 LSB, 0.411 LSB 16.12 316 µA, 332 kΩ, 662 µA, 166 kΩ 16.16 (a) 693 µA, 93.8 kΩ, 1.11 mA, 56.8 kΩ 16.18 422 kΩ, 112 µA; 498 kΩ, 112 µA 16.21 202 µA, 327 µA 16.22 472 µA, 759 µA; 479 µA, 759 µA; 430 µA, 692 µA 16.24 63.8 kΩ, 11.8 µA, 123 µA 16.26 10 16.28 15 kΩ, 2/3 16.30 138 µA, 514 MΩ 16.32 4.90 kΩ 16.34 172 kΩ, 15.0 kΩ, 0.445 16.36 21.8 µA, 18.4 MΩ; 43.7 µA, 9.17 MΩ 16.38 29.8 µA, 92.9 MΩ; 87.9 µA, 31.5 MΩ; 2770; 1.40 V 16.42 17.0 µA, 80/1; 89.9 MΩ 16.44 2/gm2 16.46 5.49/1 16.49 11.7 MΩ, 0, 6.687, 90.4 MΩ 16.51 1.33 MΩ, 1, 126, 84.4 MΩ 16.52 20.0 µA, 953 MΩ; 19.1 kV; 2.21 V 16.54 21.0 µA, 4.40 nA 16.57 (b) 50 µA, 240 MΩ; 12.0 kV; 3.05 V 16.60 16.9 µA, 163 MΩ, 2750 V; 2VBE = 1.40 V 16.62 2.86 kΩ 37 16.64 (a) 102 GΩ 16.66 (a) 51.0 GΩ 16.68 (a) 64.0 µA, 3.10 MΩ 16.70 5.71 kΩ 16.72 317 µA; 295 µA; 66.5 µA 16.74 " #oro4 2 16.76 14.5 kΩ, 226 kΩ ! 16.78 11.5 kΩ, 313 kΩ I I "2 "2 16.80 IC1 = 137 µA, IC1 = 44.8 µA, SVCCC 1 = 4.40x10 , SVCCC 2 = 1.54 x10 16.82 n > 1/3 ! 16.84 6.24 mA I D1 D2 = 7.75x10"2 SVIDD = 6.31x10"2 16.86 (b) ID1 = 8.19 µA ID2 = 7.24 µA SVDD The currents differ considerably from the hand calculations. The currents are quite sensitive to the value of λ. The hand calculations used λ = 0. If the simulations are run with λ = 0, then the results are identical to the hand calculations. ! 16.88 14.4 µA, 36.0 µA, 6.56 µA, 72.0 µA, 9.48 µA 16.90 IC2 = 16.9 µA IC1 = 31.5 µA - Similar to hand calculations. SVICCC 1 = 9.36x10"3 SVICCC 2 = 2.64 x10"3 16.92 (a) 388 µA, 259 µA ! 16.94 110 µA 16.96 4.90 V, 327.4 K 16.98 1.20 V, 304.9 K 16.100 5.07 V, +44.0 µV/K 16.102 -472 µV/K, -199 µV/K 16.104 2.248 kΩ, 10.28 kΩ, 80 kΩ, 23.9 kΩ, 126 kΩ 16.105 79.1, 6.28 x10-5, 122 dB 16.107 47.2, 6.97 x10-5, 117 dB 16.109 1200, 4 x10-3, 110 dB, ±2.9 V 16.113 (100 µA, 8.70 V), (100 µA, 7.45 V), (100 µA, -2.50 V), (100 µA, -1.25 V), 324, 152 16.115 (125 µA, 1.54 V), (125 µA, -2.79 V), (125 µA, 2.50 V), (125 µA, 1.25 V); 19600 38 16.118 171 µA 16.119 (b) 100 µA 16.120 (250 µA, 5.00 V), (250 µA, 5.00 V), (250 µA, -1.75 V), (250 µA, -1.75 V), (500 µA, -3.21 V), (135 µA, 5.00 V), (135 µA, -5.00 V), (250 µA, 2.16 V), (500 µA, 3.25 V), (500 µA, 3.21 V), (500 µA, 3.58 V); 4130; 2065 16.122 12,600 16.124 (250 µA, 7.50 V), (250 µA, 7.50 V), (250 µA, -1.75 V), (250 µA, -1.75 V), (1000 µA, -5.13 V), (330 µA, 7.50 V), (330 µA, -7.50 V), (1000 µA, 4.75 V), (250 µA, 2.16 V), (500 µA, 5.75 V), (1000 µA, 5.13 V), 3160 16.126 (b) 42.9/1 (c) 23000 16.130 7.78, 574 Ω, 3.03 x 105, 60.0 kΩ 16.132 ±1.4 V, ±2.4 V 16.133 (a) 9.72 µA, 138 µA, 46.0 µA 16.134 271 kΩ, 255 Ω 16.136 VEE ≥ 2.8 V, VCC ≥ 1.4 V; 3.8 V, 2.4 V 16.138 2.84 MΩ, 356 kΩ. 6.11 x 105 16.141 100 µA, 15.7 V), (100 µA, 15.7 V), ( (50 µA, -12.9 V), (50 µA, -0.700 V), (50 µA, -0.700 V), (50 µA, -12.9 V), (50 µA, 1.40 V), (50 µA, 1.40 V), (2.00 µA, 29.3 V), (100 µA, 0.700 V), (100 µA, 13.6 V); 1.00 mS, 752 kΩ 16.142 (50 µA, 15.7 V), (50 µA, 15.7 V), (50 µA, 12.9 V), (50 µA, 12.9 V), (50 µA, 1.40 V), (50 µA, 1.40 V), (1.00 µA, 29.3 V), (100 µA, 1.40 V), (1 µA, 0.700 V), (1 µA, 13.6 V); 1.00 mS, 864 kΩ 16.143 (50 µA, 2.50 V), (25 µA, 3.20 V) 16.144 (a) 125 µA, 75 µA, 62.5 µA, 37.5 µA, 16.146 (500 "195sin 5000#t )µA, (500 + 195sin 5000#t )µA; 0.488 mS ! 39 Chapter 17 17.1 Amid = 50, FL ( s) = 17.4 200, 17.7 200, ! ! 17.9 s2 s , yes, Av ( s) " 50 , 4.77 Hz, 4.82 Hz (s + 4)(s + 30) (s + 30) 1 , yes, 1.59 kHz, 1.58 kHz " s %" s % $ 4 + 1'$ 5 + 1' #10 &# 10 & s2 1 , , 0.356 Hz, 142 Hz; 0.380 Hz, 133 Hz (s + 1) s( + 2) ! s $! s $ #1 + 500& #1+ 1000 & " %" % (b) -14.3 (23.1 dB), 11.3 Hz 17.10 (b) -15.6, 8.15 Hz 17.11 1.52 µF; 1.50 µF, 49.4 Hz 17.13 0.213 µF; 0.22 µF; 1940 Hz 17.14 Av ( s) = Amid s2 | " = (s + "1)(s + "2 ) 1 1 # 1& C1% RS + RE ( gm ' $ | "2 = 1 C2 ( RC + R3 ) 35.5 dB, 13.2 Hz; -5.0 V, 7.9 V ! 17.16 123 Hz; 91 Hz; (145 µA, 3.57 V) 17.18 -131, 49.9 Hz, 12.0 V 17.19 45.5 Hz 17.21 7.23 dB, 19.8 Hz 17.23 0.739, 11.9 Hz, 10.0 V 17.24 0.15 µF 17.25 1.8 µF 17.27 Cannot reach 2 Hz; fL = 13.1 Hz for C1 = ∞, limited by C3 17.29 0.15 µF 17.30 308 ps 17.33 (a) 22.5 GHz 17.34 −96.7; −110 17.35 0.978; 0.979 40 | 2 zeros at " = 0 17.37 (a) −5100, −98.0, −5000, −100, 2% error (b) −350, −42.9, −300, −50, 18% error 17.39 Real roots: -100, -20, -15, -5 17.41 (3.31 mA, 2.71 V); -89.6, 1.45 MHz; 130 MHz 17.43 -14.3, 540 kHz 17.45 (0.834 mA, 2.41 V); -8.27, 3.29 MHz; 27.2 MHz 17.49 61.0 pF, 303 MHz 17.52 1/105 RC; 1/106 RC; -1/sRC 17.54 39.2 dB, 5.51 MHz 17.56 -114, 1.11 MHz; 127 MHz, 531 MHz 17.59 680 Ω, -18.0, 92.7 MHz 17.60 -29.3, 7.41 MHz, 227 MHz 17.62 300 Ω, 1 kΩ 17.63 −1300; −92.3; −100, −1200 17.64 9.55, 64.4 MHz 17.66 59.7, 1.72 MHz 17.69 2.30, 14.1 MHz 17.70 3.17, 14.1 MHz, 15.4 Hz 17.71 0.960, 114 MHz 17.74 -1.56 dB, 73.3 MHz 17.75 CGD + CGS/(1 + gm RL) for ω << ωT 17.77 Using a factor of 2 margin: 8 GHz, 19.9 ps 17.81 672 mA - not a realistic design. A different FET is needed. 17.83 393 kHz; 640 kHz 17.87 294 kHz 17.89 48.2 kHz 17.90 52.9 kHz 17.92 (a) 568 kHz 17.94 (a) 2.01 MHz 17.96 53.4 dB, 833 Hz, 526 kHz 17.97 1.52 MHz; 323 µH, 3.65 MHz 17.99 -45o; -118o; -105o 41 17.101 22.5 MHz, -41.1, 2.91 17.102 20.1 pF; 12.6; n = 2.81; 21.8 pF 17.103 15.2 MHz; 27.5 MHz 17.104 13.4 MHz, 7.98, 112/−90°; 4.74 MHz, 5.21, 46.1/−90° 17.105 10.1 MHz, 3.96, −35.3; 10.94 MHz, 16.8, −75.1 17.108 65 pF; 240, -4.41x104, 25.1 kHz 17.110 62.3 pF; 152 kHz, 40 17.112 (b) 497 Ω, 108 pF 17.113 100 Ω, 104 fF; 52.2 Ω, 144 fF 17.117 (a) 100 MHz, 1900 MHz 17.119 58.9 dB 17.121 -19.5 dB; -23.9 dB 17.123 0.6 A 17.125 -13.5 dB; -17.9 dB 17.127 0.2 A 17.129 1, 0.5, 0.5 17.131 0.567 V 17.133 0.2I1RC 42 Chapter 18 18.1 (b) 200, 4.975, 0.498% 18.3 1/40, 790.6, -38.95 18.5 104 dB 18.7 1/(1+T); 0.0498 % 18.9 (a) Series-shunt feedback (b) Shunt-series feedback 18.13 857 Ω, 33.3, 57.1, 506 Ω 18.15 245 Ω, 0, 0.952, 126 Ω 18.17 8.33x105, 16.7 S 18.19 12.9, 8.88 MΩ, 1.52 Ω 18.21 31.1 Ω, 2.01, 17.9, 195 Ω 18.23 10.1, 252 kΩ, 358 Ω 18.25 2.66 Ω; (32.2 Ω, 0, 11.1) 18.27 141 Ω; (13.0 kΩ, 0, 91.2) 18.29 0.9987, 110.4 MΩ, 2.845 Ω vs. 0.999, 108 MΩ, 2.70 Ω 18.31 −39.0 kΩ, 8.31 Ω, 0.295 Ω 18.33 33.2 Ω, 45.6 Ω, −38.9 kΩ 18.35 29.7 kΩ, 1.48 kΩ, -672 kΩ 18.37 0.133 mS, 60.4 MΩ, 26.8 MΩ 18.39 SPICE Results : Atc = 9.92x10"5 S Rin = 144.1 M# Rout = 11.91 M# Hand Calculations: Atc = 9.92x10 S Rin = 148 M# "5 18.41 0.467 mS, 95.0 MΩ ! 18.42 8.48, 15.1 Ω, 3.51 MΩ 18.43 400 Ω, 12.5 MΩ, 0.992 18.45 29.8 MΩ, 799 MΩ, 1.08 GΩ 18.47 2.97, 14.5 Ω, 24.3 MΩ; 2.99, 14.6 Ω, 18.1 MΩ 18.49 30.39 GΩ; 33.3 GΩ 18.51 47.32 MΩ; 37.5 MΩ 18.53 Tv = 105, Ti = 18.1, T = 15.2, R2 R1 = 5.55 ! 43 Rout = 11.1 M# 18.55 Tv = 988, Ti = 109, T = 98.0, R2 R1 = 8.99 18.57 110 kHz, 2048, ≤ 2048 ! 18.59 219 pF 18.61 76.6o 18.63 107o 18.67 9.38 MHz, 41.7 V/µS 18.69 (b) 95.5 MHz, 30 V/µS 18.71 ±8.57 V/µS 18.73 71.5 MHz, 11.4 kHz, 236 MHz, 326 MHz, 300 MHz; 84.4 dB; < 0; 16.8 pF 18.75 12 kΩ; 9.05 MHz, 101 MHz, 74.8 MHz, 320 MHz; 2.60 MHz, 44.6 pF 18.77 (a) 81.9o 18.79 6.32 pF; 315 MHz, 91.5 MHz; 89.4o 18.81 17.5 MHz; [20.1 MHz, 36.3 MHz]; 0.211 mS, 5.28 µA 18.82 5.17 MHz, 4.53 MHz 18.84 9.00 MHz, 1.20 18.86 7.96 MHz, 8.11 MHz, 1.05 18.88 7.5 MHz, 80 Vp-p 18.89 7.96 MHz 18.90 11.1 MHz, 18.1 MHz, 1.00 ! ! 18.91 LEQ = L1 + L2 | REQ = "# 2 g m L1L2 18.92 " o2 = 1 L(C + CGS + 4CGD ) | µf # 1+ ro RP 18.94 5.13 pF; 1 GHz can't be achieved. 18.95 6.33 pF; 2.81 mA; 3.08 mA; 1.32 V 18.97 15.915 mH, 15.915 fF; 10.008 MHz, 10.003 MHz 18.99 9.28 MHz; 9.19 MHz Congratulations! you have just conquered most of electrical engineering! except for Ch 18, now where did that go? 44

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