4. TTL = Transistor-Transistor Logic. Uses bipolar transistors and diodes Vcc IN1 L L H H R IN1 OUT IN2 IN2 L H L H OUT L L L H Diode Logic AND gate Problem… defined levels change easily when loaded. E.g. when diode gates are cascaded. Need for transistor buffering Vcc R IN1 IN2 Vi R OUT IN1 L L H H IN2 L H L H NAND gate! OUT H H H L TTL: practical realisation Diode AND gate Dynamic resistance: lower ON (L) voltage, faster switching Limits current in transition Totem Pole Output Schottky Diodes Clamp diodes TTL Logic families and specs • • • • • • • Vcc=5V±10%, Vohmin=2.7V, Vihmin=2.0V, Volmax=0.5V, Vilmax=0.8V NMh = 0.7V, NML=0.3V Families: TTL e.g. 7404, 74H04, 74L04 original family – Schottky e.g. 74S04: faster, hi power consumption – Low Power Schottky e.g. 74LS04: lower Pd, Slower Schottky (common) – Advanced Schottky e.g. 74AS04 2x speed of S, same Pd – Adv. Low Pwr Sky e.g. 74ALS04 see table 3-11, Wakerly For LS, typically: IILmax=-0.4mA, IIHmax=20uA, IOLmax=8mA, IOHmax=-400uA. FANOUT (LSTTL into LSTTL)=20 NB: TTL outputs can sink more current than they can source. TTL vs CMOS TTL CMOS Noise Margins 0.3(high), 0.5 (low) 0.3Vcc Input source currents High in both states: 0.2 to 2mA(L), 20-50uA (H) Typ < 1uA in both states Power Consumption Relatively high, fixed. 2mW for 74LS, 20mW for 74Sxx. Depends on Vcc, frequency. Negligible static dissipation. Very low for FCTT Output drive current Asymmetric: High state: 0.4-2mA Low state: 8 – 20mA Symmetric: Typ 4mA but AC family can drive 24mA Power supply voltage 5V ±10% 3V Vcc 18V (original 4000 family), 2V Vcc 6V (newer HC family) Interconnectio n (CMOS to TTL, TTL to CMOS) Cannot drive CMOS since VOHMIN(TTL)<VIHMIN(CMOS) Pullup resistor needed unless using TTL compatible family e.g. HCT Can directly drive TTL Applications: CMOS/TTL interfacing VOHMIN, VOLMAX VIHMIN, VILMAX 3.5 VOHMIN, VOLMAX VIHMIN, VILMAX 4.9 2.0 2.7 1.5 0.5 TTL CMOS 0.8 0.1 CMOS TTL 5. Applications: Unused inputs Floating inputs can lead to unreliable operation!!! Unused (Floating) Inputs [] Tie together and bundle with used inputs OR [] Tie HIGH thru pull up resitor, Rpu OR Must ensure that [] Tie LOW thru pull down resistor, Rpd does not affect [] For CMOS use 1K-10K values design function. [] For TTL calculate based on # of inputs tied thru E.g. tie HIGH for AND/NAND or resistor so that: LOW for Vcc-RpuIIHmax > VIHmin OR/NOR RpdIILmax < VILmax []Too small Rpu makes TTL susceptible to spikes etc. over 5.5V. See Sec 3.10.4, 3.5.6 Wake. Power supply filtering • For each logic IC place a small capacitor (0.01uF tp 0.1uF) across Vcc and ground in close proximity to the IC • Reduces transient effect of switching on power supply, particularly when supply source is connected via long circuit path (resistive and inductive effects). Essentially each capacitor provides a local reservoir for fast supply of charge required when the device switches Applications: Open-drain (CMOS) or open collector (TTL) outputs • In CMOS no PMOS transistor, use external pull-up resistor for Vcc drive Vcc Calculate external Rpu so that VOLMAX achieved at IOLMAX. Must include other loads so this gives minimum Rpu. Vcc Rpu IC Z A Q1 B Q2 A 0 0 1 1 B 0 1 0 1 Q1 open open ON ON Q2 open ON open ON Output stage of Open Drain NAND Z 1 1 1 0 Why ? • Slightly higher current capability • Can form an open-drain/collector bus. Can select data for access to common bus.. E.g for Dataout = Datai set Enablej =0, jI, Enablei =1, Problem -- really bad rise time due to all O/P capacitances in parallel and large pullup. Applications: Bus Access - Contention and Tristate Logic Common bus 0 a Best “fix”….Tristate logic Vin 1 Vout EN 1 b 0 ?? “regular TTL or CMOS •Get bus contention when two outputs try to drive the bus to different states. • Value on the bus may be indeterminate; •Damage possible (a driving b!!) •On a PC data bus, can cause PC to crash EN 0 1 1 Vin x 1 0 Vout HiZ 0 1 •Available in inverting or non-inverting .. Sec 3.7.3 Wakerly. •NO Pull-up needed •NO degradation in transition speed Applications: Digital meets analog Schmitt Trigger Inputs…Sec3.7.2/Wakerly • Schmitt trigger devices are used primarily to deal with signal levels which are not at valid logic levels. They can therefore be used for • interfacing noisy analogue signals to a logic circuit e.g. signals from switches, RC networks etc. • interfacing slow signals (i.e. signals which remain in the invalid range for relatively long periods) • regenerating degraded logic signals e.g. signals on a long serial communication line. Schmitt trigger devices do comply with the input thresholds of the respective family. However, they employ a bit of hysterisis (memory!!) to take care of invalid signal levels. The devices are characterised by upper and lower thresholds (UT, LT). When the input exceeds UT it is treated as a logic 1 UNTIL it goes below LT. Then, and only then, is it treated as a logic 0. Vo Vi Vo LT Vo UT Last level is latched until opposite threshold is crossed VL VH Vi Schmitt Trigger o/p Characteristic VT Vi Standard logic o/p Characteristic Applications: Logic Drive Driving a LED with TTL Vcc ILED R VLED Logic Device VOL Low output turns LED ON Drive current typ 5 -10mA Use buffers for extra drive • ILED is 10mA typically worst case • Use formula: VOL+VLED+(ILED*R)=VCC to determine R. NB……. • Can assume worst case VOL=VOLMAX for some CMOS as well as TTL at IOL=ILED. • Best to use device for which IOLMAX>ILED. Applications: Logic Drive Driving a Solenoid or relay with TTL Vcc Free-wheeling diode protects electronics from coil back emf Logic Device Low output turns activates relay or solenoid • 5V relays do exist. • Some incorporate the free wheeling Diode. • Most have enough internal resistance to operate directly as shown. • Check using LED computation if built in resistance is sufficient or if an external series resitance is needed