Optically-Coupled Linear ISOLATION AMPLIFIER ISO100

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ISO100
ISO
100
Optically-Coupled Linear
ISOLATION AMPLIFIER
FEATURES
APPLICATIONS
● EASY TO USE, SIMILAR TO AN OP AMP
VOUT/IIN = RF, Current Input
VOUT/VIN = RF/RIN, Voltage Input
● 100% TESTED FOR BREAKDOWN:
750V Continuous Isolation Voltage
● ULTRA-LOW LEAKAGE: 0.3µA, max, at
240V/60Hz
● WIDE BANDWIDTH: 60kHz
● INDUSTRIAL PROCESS CONTROL
Transducer Sensing
(Thermocouples, RTD, Pressure Bridges)
4mA to 20mA Loops
Motor and SCR Control
Ground Loop Elimination
● BIOMEDICAL MEASUREMENTS
● TEST EQUIPMENT
● 18-PIN DIP PACKAGE
● DATA ACQUISITION
DESCRIPTION
The ISO100 is an optically-coupled isolation amplifier. High accuracy, linearity, and time-temperature
stability are achieved by coupling light from an LED
back to the input (negative feedback) as well as forward to the output. Optical components are carefully
matched and the amplifier is actively laser-trimmed to
assure excellent tracking and low offset errors.
The circuit acts as a current-to-voltage converter with
a minimum of 750V (2500V test) between input and
output terminals. It also effectively breaks the galvanic connection between input and output commons
as indicated by the ultra-low 60Hz leakage current of
0.3µA at 250V. Voltage input operation is easily
achieved by using one external resistor.
Versatility along with outstanding DC and AC performance provide excellent solutions to a variety of
challenging isolation problems. For example, the
ISO100 is capable of operating in many modes, including: noninverting (unipolar and bipolar) and inverting (unipolar and bipolar) configurations. Two
precision current sources are provided to accomplish
bipolar operation. Since these are not required for
unipolar operation, they are available for external use
(see Applications section).
Designs using the ISO100 are easily accomplished
with relatively few external components. Since VOUT
of the ISO100 is simply IINRF, gains can be changed
by altering one resistor value. In addition, the ISO100
has sufficient bandwidth (DC to 60kHz) to amplify
most industrial and test equipment signals.
IREF1
Balance
RF IREF2
7
16 13 14
+In
–In
Balance
8
5
6
15
17
A1
3
A2
D1
VOUT
D2
LED
12 10
–VCC +VCC
18
Input
Common
9
4
2
Output –VCC +VCC
Common
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
©
1982 Burr-Brown Corporation
PDS-456G
1
ISO100
Printed in U.S.A. August, 1997
SPECIFICATIONS
ELECTRICAL
At TA = +25°C and ±VCC = 15VDC, unless otherwise specified.
ISO100AP
PARAMETER
ISOLATION
Voltage
Rated Continuous, AC peak or DC(1)
Test Breakdown, DC
Rejection(2) DC
CONDITIONS
MIN
10s
750
2500
Impedance
Leakage Current
TYP
REFERENCE CURRENT SOURCES
Magnitude
Nominal
vs Temperature
vs Power Supplies
Matching
Nominal
vs Temperature
vs Power Supplies
Compliance Voltage
Output Resistance
500
5
105
300
2
✻
200
2
✻
µV
µV/°C
dB
µV/kHr
200
2
✻
µV
µV/°C
dB
µV/kHr
nA/V
dB
V
✻
150
✻
µA
ppm/°C
nA/V
✻
0.22
TEMPERATURE RANGE
Specification
Operating
Storage
✻
300
2
✻
✻
✻
✻
✻
✻
✻
12.5
300
3
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
2 x 109
✻
✻
nA
ppm/°C
nA/V
V
Ω
60
5
0.31
100
✻
✻
✻
✻
✻
✻
✻
✻
kHz
kHz
V/µs
µs
–10
0.1%
V
V
pA/V
dB
pA/V
dB
Ω||pF
µA, rms
✻
50
150
0.3
Gain = 1V/µA
Gain = 1V/µA, VO = ±10V
UNITS
✻
✻
✻
✻
✻
✻
0.3
MAX
✻
±10
12
TYP
0.3
1
3
90
10.5
MIN
✻
✻
500
5
105
60Hz, RF = 1MΩ
RIN = 10kΩ, Gain = 100
MAX
✻
✻
✻
✻
✻
1
Common-Mode Range
FREQUENCY RESPONSE
Small Signal Bandwidth
Full Power Bandwidth
Slew Rate
Settling Time
MIN
ISO100CP
✻
✻
240Vrms, 60Hz
OFFSET VOLTAGE (RTI)
Input Stage (VOSI)
Initial Offset
vs Temperature
vs Input Power Supplies
vs Time
Output Stage (VOSO)
Initial Offset
vs Temperature
vs Output Power Supplies
vs Time
Common-Mode Rejection Ratio(2)
MAX
5
146
400
108
1012||2.5
RIN = 10kΩ, Gain = 100
60Hz, 480V, RF = 1MΩ
RIN = 10kΩ, Gain = 100
AC
TYP
ISO100BP
+15
–25
–40
–40
✻
✻
✻
✻
✻
✻
+85
+100
+100
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
°C
°C
°C
–0.02
+1
✻
✻
✻
✻
✻
✻
✻
✻
0
✻
✻
✻
µA
mA
Ω
V
Ω
UNIPOLAR OPERATION
GENERAL PARAMETERS
Input Current Range
Linear Operation
Without Damage
Input Impedance
Output Voltage Swing
Output Impedance
GAIN
Initial Error (adjustable to zero)
vs Temperature
vs Time
Nonlinearity(3)
–20
–1
✻
0.1
RL = 2kΩ, RF = 1MΩ
DC, Open-Loop
–10
✻
✻
1200
✻
✻
VO = RF (IIN)
2
0.03
0.05
0.1
5
0.07
0.4
1
0.01
✻
0.03
2
0.05
0.1
1
0.005
✻
0.02
2
0.03
0.07
% of FS
%/°C
%/kHr
%
IIN = 0.2µA
CURRENT NOISE
0.01Hz to 10Hz
10Hz
100Hz
1kHz
20
1
0.7
0.65
ISO100
2
✻
✻
✻
✻
✻
✻
✻
✻
pAp-p
pA/√Hz
pA/√Hz
pA/√Hz
SPECIFICATIONS
(CONT)
ELECTRICAL
At TA = +25°C and ±VCC = 15VDC, unless otherwise specified.
ISO100AP
PARAMETER
CONDITIONS
MIN
INPUT OFFSET CURRENT (IOS)
Initial Offset
vs Temperature
vs Power Supplies
vs Time
POWER SUPPLIES
Input Stage
Voltage (rated performance)
Voltage (derated performance)
Supply Current
IIN = –0.02 µA
IIN = –20µA
Output Stage
Voltage (rated performance)
Voltage (derated performance)
Supply Current
Short Circuit Current Limit
±7
±7
VO = 0
ISO100BP
TYP
MAX
1
0.05
0.1
100
10
MIN
±15
±1.1
TYP
MAX
✻
✻
✻
✻
✻
MIN
✻
±18
±1.1
±2
+8, –1.1 +13, –2
±15
ISO100CP
✻
✻
✻
✻
+10
+1
✻
✻
+10
✻
✻
MAX
UNITS
✻
✻
✻
✻
✻
nA
nA/°C
nA/V
pA/kHr
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
±18
±2
±40
TYP
✻
✻
✻
V
V
mA
mA
✻
✻
✻
V
V
mA
mA
✻
✻
BIPOLAR OPERATION
GENERAL PARAMETERS
Input Current Range
Linear Operation
Without Damage
Input Impedance
Output Voltage Swing
Output Impedance
–10
–1
GAIN
Initial Error (Adjustable To Zero)
vs Temperature
vs Time
Nonlinearity(3)
CURRENT NOISE
0.01Hz to 10Hz
10Hz
100Hz
1kHz
–10
Output Stage
Voltage (rated performance)
Voltage (derated performance)
Supply Current
Short Circuit Current Limit
✻
✻
1200
✻
✻
µA
mA
Ω
V
Ω
VO = RF (IIN)
2
0.03
0.05
0.1
5
0.07
1
0.01
✻
0.03
0.4
2
0.05
1
0.005
✻
0.02
0.1
2
0.03
0.07
% of FS
%/°C
%/kHr
%
IIN = 0.2µA
✻
✻
✻
✻
1.5
17
7
6
INPUT OFFSET CURRENT (IOS, bipolar(4))
Initial Offset
vs Temperature
vs Power Supplies
vs Time
POWER SUPPLIES
Input Stage
Voltage (rated performance)
Voltage (derated performance)
Supply Current
✻
0.1
RL = 2kΩ, RF = 1MΩ
✻
✻
40
200
3
0.7
20
IIN = +10µA
IIN = –10µA
±7
VO = 0
±15
±1.1
10
✻
✻
✻
✻
✻
35
1
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
±18
±2
±40
nA, p-p
pA/√Hz
pA/√Hz
pA/√Hz
✻
✻
±18
+2, –1.1 +3, –2
+8, –1.1 +13, –2
±15
70
2
✻
✻
250
±7
✻
✻
✻
✻
✻
✻
✻
V
V
mA
mA
✻
✻
✻
V
V
mA
mA
✻
✻
nA
nA/°C
nA/V
pA/kHr
✻ Same as ISO100AP.
NOTES: (1) See Typical Performance Curves for temperature effects. (2) See Theory of Operation section for definitions. For dB see Ex. 2, CM and HV errors.
(3) Nonlinearity is the peak deviation from a “best fit” straight line expressed as a percent of full scale output. (4) Bipolar offset current includes effects of reference
current mismatch and unipolar offset current.
The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN
assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject
to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not
authorize or warrant any BURR-BROWN product for use in life support devices and/or systems.
3
ISO100
PIN CONFIGURATION
ABSOLUTE MAXIMUM RATINGS
Supply Voltages ................................................................................. ±18V
Isolation Voltage, AC pk or DC ......................................................... 750V
Input Current ..................................................................................... ±1mA
Storage Temperature Range ......................................... –40°C to +100°C
Lead Temperature (soldering, 10s) ............................................... +300°C
Output Short-Circuit Duration ................................ Continuous to Ground
Bottom View
ISO100
Input Common 18
1
NC(1)
–In 17
2
+VCCA2
Ref1 16
3
VOUT
+In 15
4
–VCCA2
5
Bal
Bal 13
6
Bal
–VCCA1 12
7
RF
(1)
11
8
Ref2
+VCCA1 10
9
Output Common
Bal 14
NC
A1
A2
PACKAGE INFORMATION
PRODUCT
PACKAGE
PACKAGE DRAWING
NUMBER(1)
ISO100AP
ISO100BP
ISO100CP
18-Pin Bottom-Braze DIP
18-Pin Bottom-Braze DIP
18-Pin Bottom-Braze DIP
220
220
220
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
ELECTROSTATIC
DISCHARGE SENSITIVITY
NOTE: (1) No internal connection.
This integrated circuit can be damaged by ESD. Burr-Brown
recommends that all integrated circuits be handled with
USA OEM PRICES
appropriate precautions. Failure to observe proper handling
1-24
25-99
100+
and installation procedures can cause damage.
ORDERING INFORMATION
PRODUCT
PACKAGE
TEMPERATURE RANGE
ISO100AP
ISO100BP
ISO100CP
18-Pin Bottom-Braze DIP
18-Pin Bottom-Braze DIP
18-Pin Bottom-Braze DIP
–25°C to +85°C
–25°C to +85°C
–25°C to +85°C
ISO100
$53.18
$40.94
$32.21
ESD
from subtle performance
57.94damage can range 45.02
36.22 degrada64.62
51.69
42.48 circuits
tion
to complete device failure.
Precision integrated
may be more susceptible to damage because very small
parametric changes could cause the device not to meet its
published specifications.
4
TYPICAL PERFORMANCE CURVES
At TA = +25°C, ±VCC = 15VDC, unless otherwise specified.
SMALL SIGNAL FREQUENCY RESPONSE
BIPOLAR OUTPUT SWING vs RF
20
±20
±18VCC
10
±15
Output Swing (V)
Amplitude (dB)
No CF
0
–10
CF = 4pF
–20
±13VCC
±10VCC
±10
Output Stage
Power Supply
±7VCC
±5
–30
VO = (12µA) (RF)
= |VCC| – 1.2V max
–40
0
1
10
100
1000
10k
100k
1M
Frequency (kHz)
10M
100M
RF (Ω)
BIPOLAR INPUT STAGE SUPPLY CURRENT
vs INPUT CURRENT
PHASE SHIFT vs FREQUENCY
0
10
90
5
Phase (degrees)
Supply Current (mA)
No CF
+VCC
0
–VCC
180
CF = 4pF
270
–5
–10
–20
–10
0
10
20
1
10
100
Frequency (kHz)
UNIPOLAR OUTPUT SWING vs RF
UNIPOLAR INPUT STAGE SUPPLY CURRENT
vs INPUT CURRENT
0
10
VO = (12µA) (RF)
= |VCC| – 1.2 V max
Not specified for
operation in this region.
Output Swing (V)
Supply Current (mA)
±7VCC
–5
±10VCC
–10
–15
1000
IIN (µA)
±13VCC
Output Stage
Power Supply
±18VCC
5
+VCC
0
–VCC
–5
Short circuit
current limit.
–30
–20
10k
100k
1M
10M
100M
–20
RF (Ω)
–10
0
IIN (µA)
5
ISO100
10
20
TYPICAL PERFORMANCE CURVES (CONT)
At TA = +25°C, ±VCC = 15VDC, unless otherwise specified.
CONTINUOUS DC ISOLATION VOLTAGE
vs TEMPERATURE
15
2
10
Max at 60Hz
1
5
Typ at 60Hz
1250
Continuous DC Isolation Voltage (V)
3
DC Leakage Current (nA)
AC Leakage Current (µArms)
ISOLATION LEAKAGE CURRENT
vs ISOLATION VOLTAGE
Typ at DC
0
1000
0
0
1
Recommended
Operating Region
500
65°C
250
85°C
0
3
2
750
–25
0
25
Isolation Voltage (kV)
AC ISOLATION VOLTAGE vs TEMPERATURE
Rate of Change of Gain Error (%/hr)
AC Isolation Voltage (Vp)
100
125
RATE OF GAIN ERROR SHIFT vs ISOLATION VOLTAGE
1000
750
Recommended
Operating Region
250
85°C
Short term shift (10 hrs)
1
Temp = +85°C
Long term
shift is random.
0.5
Temp = up to +65°C
0
0
–25
0
25
50
100
0
125
GAIN ERROR
vs TEMPERATURE AND ISOLATION VOLTAGE
3
2.5
VIM >VT
2
VIM < VT
1.5
1
0.5
0
–25
0
25
50
65 75
TT
100
125
Temperature (°C)
NOTES: VT and TT approximate the threshold
for the indicated gain shift. This is
caused by the properties of the optical
cavity.
TT ≈ +65°C, VT ≈ 200VDC. Shift does
not occur fo AC voltages.
ISO100
250
500
750
Isolation Voltage (VDC)
Temperature (°C)
Gain Error (Normalized to +25°C)
75
1.5
1250
500
50
Temperature (°C)
VIM = Isolation-Mode Voltage
VT = Threshold Voltage
TT = Threshold Temperature
6
1000
THEORY OF OPERATION
the LED. As the LED light output increases, D1 responds by
generating an increasing current. The current increases until
the sum of the currents in and out of the input node (–Input
to A1) is zero. At that point, the negative feedback through
D1 has stabilized the loop, and the current ID1 equals the
input current plus the bias current. As a result, no bias
current flows in the source. Since D1 and D2 are matched
(ID1 = ID2), IIN is replicated at the output via D2. Thus, A1
functions as a unity-gain current amplifier, and A2 is a
current-to-voltage converter, as described below.
The ISO100 is fundamentally a unity gain current amplifier
intended to transfer small signals between electrical circuits
separated by high voltages or different references. In most
applications, an output voltage is obtained by passing the
output current through the feedback resistor (RF).
The ISO100 uses a single light emitting diode (LED) and a
pair of photodiode detectors coupled together to isolate the
output signal from the input.
Current produced by D2 must either flow into A2 or RF.
Since A2 is designed for low bias current (≈10nA), almost all
of the current flows through RF to the output. The output
voltage then becomes:
Figure 1 shows a simplified diagram of the amplifier. IREF1
and IREF2 are required only for bipolar operation to generate
a midscale reference. The LED and photodiodes (D1 and D2)
are arranged such that the same amount of light falls on each
photodiode. Thus, the currents generated by the diodes
match very closely. As a result, the transfer function depends upon optical match rather than absolute performance.
Laser-trimming of the components improves matching and
enhances accuracy, while negative feedback improves linearity. Negative feedback around A1 occurs through the
optical path formed by the LED and D1. The signal is
transferred across the isolation barrier by the matched light
path to D2.
VO = (ID2)RF = (ID1 ±IOS)RF ≈ –(–IIN)RF = IINRF
where, IOS is the difference between A1 and A2 bias currents.
For input voltage operation IIN can be replaced by a voltage
source (VIN) and series resistor (RIN), since the summing
node of the op amp is essentially at ground. Thus, IIN =
VIN/RIN.
Unipolar operation does have some constraints, however. In
this mode the input current must be negative so as to produce
a positive output voltage from A1 to turn the LED on. A
current more negative than 20nA is necessary to keep the
LED turned on and the loop stabilized. When this condition
is not met, the output may be indeterminant. Many sensors
generate unidirectional signals, e.g., photoconductive and
photodiode devices, as well as some applications of thermocouples. However, other applications do require bipolar
operation of the ISO100.
The overall isolation amplifier is noninverting (a positive
going input produces a positive going output).
INSTALLATION AND
OPERATING INSTRUCTIONS
UNIPOLAR OPERATION
In Figure 1, assume a current, IIN, flows out of the ISO100
(IIN must be negative in unipolar operation). This causes the
voltage at pin 15 to decrease. Because the amplifier is
inverting, the output of A1 increases, driving current through
BIPOLAR OPERATION
To activate the bipolar mode, reference currents as shown in
Figure 1 are attached to the input nodes of the op amps. The
input stage stabilizes just as it did in unipolar operation.
RF
IREF1
Isolation
Barrier
16
7
Input Circuit
RIN
IREF2
8
Output Circuit
+In
15
A1
A2
3
VOUT
+
VIN
IIN
–
Optical
Assembly
D1
–In
17
(1)
D2
VOUT = IIN RF
9
LED
18
Input Common
Output Common
Connect pins 15 and 16 for bipolar,
and pins 16 and 17 for unipolar.
Connect pins 7 and 8 for bipolar,
and pins 8 and 9 for unipolar.
FIGURE 1. Simplified Block Diagram of the ISO100.
7
ISO100
Assuming IIN = 0, the photodiode has to supply all the IREF1
current. Again, due to symmetry, ID1 = ID2. Since the two
references are matched, the current generated by D2 will
equal IREF2. This results in no current flow in RF, and the
output voltage will be zero. When IIN either adds or subtracts
current from the input node, the current D1 will adjust to
satisfy ID1 = IIN + IREF1. Because IREF1 equals IREF2 and ID1
equals ID2, a current equal to IIN will flow in RF. The output
voltage is then VO = IINRF. The range of allowable IIN is
limited. Positive IIN can be as large as IREF1 (10.5µA, min).
At this point, D1 supplies no current and the loop opens.
Negative IIN can be as large as that generated by D1 with
maximum LED output (recommended 10µA, max).
The output then becomes:
VOUT = RF[(
±VOSO
,
UNIPOLAR ]
UNIPOLAR)
Given: IOS BIPOLAR
RIN = 100kΩ
RF = 1MΩ (gain = 10)
VOSI = +200µV
VOSO = +200µV
ID1 and ID2—currents generated by each photodiode in
response to the light from the LED.
VOS total RTO
= VOS total RTI x RF/RIN
= –21.2mV x 10
= –212mV
Ae—gain error.
Ae = | Ideal gain/Actual gain | – 1
RF(1)
VOSO
ISO100
+
Isolation
Barrier
–
+
A1
VIN
–
ID1
IOS
A2
ID2
LED
IREF1
IREF2
NOTE: (1) Use 1MΩ or greater to achieve a full scale output of 10V.
FIGURE 2. Circuit Model for DC Errors in the ISO100.
ISO100
(3)
+ VOSO/(RF/RIN)
= +35nA
VOS total RTI
= {[±VOSI ±RIN (IOS BIPOLAR) – RIN (IREF 1)]
[1 + Ae] + RIN IREF 2} ±VOSO/(RF/RIN)
= {[+200µV + 100kΩ (35nA) – 100kΩ (12.5µA)]
[1.02] + 100kΩ (12.5µA]} +
200µV/(1MΩ/100kΩ)
= {[0.2mV + 3.5mV – 1.25V]
[1.02] + 1.25V} + 0.02mV
= –21.2mV
I REF1 and I REF2 —reference currents that, when
connected to the inputs, enable bipolar operation. The two
currents are trimmed, in the bipolar mode, to minimize the
IOS BIPOLAR error.
–
±VOSO
Find: The total offset voltage error referred to the input and
output when VIN = 0V.
IOS—the offset current. This is the current at the input
necessary to make the output zero. It is equal to the
combined effect of the difference between the bias currents
of A1 and A2 and the matching errors in the optical
components in the unipolar mode.
+
± IOS
Example 1. Refer to Figure 2 and Electrical Specifications
Table.
see equation (2).
RIN
RIN
VOS (RTI) = (±VOSI) ±RIN (IOS
(4)
(1)
VOSI
– IREF1 ± IOS)(1 + Ae)+ IREF2]
(2)
This voltage is then referred back to the input by dividing by
RF/RIN.
VOSO and VOSI—the input offset voltages of the output and
input stage, respectively. VOSO appears directly at the output,
but, VOSI appears at the output as
RIN
±VOSI
VOUT ≈ RF [
A1 and A2— assumed to be ideal amplifiers.
RF
RIN
The total input referred offset voltage of the ISO100 can be
simplified in the unipolar case by assuming that Ae = 0 and
VIN = 0:
DC ERRORS
Errors in the ISO100 take the form of offset currents and
voltages plus their drifts with temperature. These are shown
in Figure 2.
VOSI
VIN ± VOS
8
VOUT
NOTE: This error is dominated by IOS BIPOLAR and the
reference current times the gain error (which appears as an
offset). The error for unipolar operation is much lower. The
error due to offset current can be zeroed using circuits shown
in Figures 6 and 7. The gain error is adjusted by trimming
either RF or RIN.
VERR is the equivalent error signal, applied in series with the
input voltage, which produces an output error identical to
that produced by application of VCM and VIM.
CMRR and IMRR are the common-mode and isolationmode rejection ratios, respectively.
Total Capacitance (C1 and C2) is distributed along the
isolation barrier. Most of the capacitance is coupled to low
impedance or noncritical nodes and affects only the leakage
current. Only a small capacitance (C2) couples to the input
of the second stage, and contributes to IMRR.
COMMON-MODE AND HIGH VOLTAGE ERRORS
Figure 3 shows a model of the ISO100 that can be used to
analyze common-mode and high voltage behavior.
Example 2. Refer to Figure 3 and Electrical Specification
Table.
Isolation Barrier
Given:
RF
RIN
–
+
C2
VIN
–
–
+
VOUT
Find: The error voltage referred to the input and output when
VIN = 0V
VERR RTI= (VCM)(CMRR)(RIN) + (VIM)(IMRR)(RIN)
= 1V (3nA/V)(100kΩ)
+ 200V (5pA/V)(100kΩ)
= 0.3mV + 0.1mV
= 0.4mV
VERR CM
+
–
+
VERR IM
–
+
C1
VCM
+
Input
Common
–
Output
Common
VIM
VCM = 1VAC peak at 60Hz, VIM = 200VDC,
CMRR = 3nA/V, IMRR = 5pA/V,
RIN = 100kΩ, RF = 1MΩ
(Gain = 10)
VERR
= 0.4mV (10)
=4mV (with DC IMRR)
FIGURE 3. High Voltage Error Model.
NOTE: This error is dominated by the CMRR term.
Definitions of CMR and IMR
IOS is defined as the input current required to make the
ISO100’s output zero. CMRR and IMRR in the ISO100 are
expressed as conductances. CMRR defines the relationship
between a change in the applied common-mode voltage
(VCM) and the change in IOS required to maintain the
amplifier’s output at zero:
CMRR (I-mode) = ∆IOS/∆VCM in nA/V
CMRR (V-mode) =
∆IOS
∆VCM
RIN =
∆VERR CM
∆VCM
For purposes of comparing CMRR and IMRR directly with
dB specifications, the following calculations can be performed:
CMRR in V/V = CMRR (I-mode)(RIN)
= 3nA/V (100kΩ) = 0.3mV/V
CMR = 20 LOG (0.3mV/V) = –70dB at 60Hz
IMRR in V/V = IMRR (I-mode)(RIN) = 5pA/V(100kΩ)
= 0.5µV/V
IMR = 20 LOG (0.5 x 10–6V/V) = –126dB at DC
(5)
in V/V (6)
IMRR defines the relationship between a change in the
applied isolation mode voltage (VIM) and the change in IOS
required to maintain the amplifier’s output to zero:
IMRR (I-mode) =
IMRR (V-mode) =
∆IOS
∆VIM
in pA/V
∆IOS
∆VIM
RIN =
= VERR RTI (RF/RIN)
RTO
Example 3.
In Example 3, VIM is an AC signal at 60Hz and
(7)
∆VERR IM
∆VIM
IMRR =
400pA
V
VERR RTI = VERR CM + VERR IM
= 0.3mV + 200V (400pA/V)(100kΩ)
= 8.3mV
VERR RTO = 83mV (with AC IMRR)
in V/V (8)
CMRR and IMRR in V/V are a function of RIN.
VIM is the voltage between input common and output common.
VCM is the common-mode voltage (noise that is present on
both input lines, typically 60Hz).
9
ISO100
OPTIONAL ADJUSTMENTS
There are two major sources of offset error: offset voltage and offset current. VOSI and VOSO of the input and output
amplifiers can be adjusted independently using external
potentiometers. An example is shown in Figure 17. Note that
VOSO (500µV, max) appears directly at the output, but VOSI
appears at the output multiplied by gain (RF/RIN). In general,
VOS is small compared to the effect of IOS (see Example 1).
To adjust for IOS use a circuit which intentionally unbalances
the offset in one direction and then allows for adjustment
back to zero.
Example 4.
Given: Total error RTO from Examples 1 and 3 as 378mV
worst case.
Find: Percent error of +10V full scale output
VERR TOTAL
% Error =
=
x 100%
VFS
378mV
x 100%
10V
= 3.78%
Figure 6 shows how to adjust unipolar errors at zero input.
The unipolar amplifier can be used down to zero input if it
is made to be “slightly bipolar.” By sampling the reference
current with R5 and R6, the minimum current required to
keep the input stage in the linear region of operation can be
established. R7 and R8 are adjusted to cancel the offset
created in the input stage. This brings the output to zero,
when the input is zero. Although the amplifier can now
operate down to zero input voltage, it has only a small
portion of the current drain and noise that the true bipolar
configuration would have.
NOISE ERRORS
Noise errors in the unipolar mode are due primarily to the
optical cavity. When the full 60kHz bandwidth is not needed,
the output noise of the ISO100 can be limited by either a
capacitor, CF, in the feedback loop or by a low-pass filter
following the output. This is shown in Figure 4. Noise in the
bipolar mode is due primarily to the reference current
sources, and can be reduced by the low-pass filters shown in
Figure 5.
Adjusting the bipolar errors is illustrated in Figure 7. Each
of the errors are adjusted in turn. With VIN = “open,”, IOS is
trimmed by adjusting R10 to make the output zero. RG is then
adjusted to trim the gain error. The effects of offset voltage
are removed by adjusting R14.
CF
15
RF
fO =
1
2πRFCF
7
R
3
ISO100
IIN
Optional Unipolar IOS Adjust.
9
1
fO =
2πRC
17
RF
1MΩ
R6
84kΩ
C
18
R5
10MΩ
IIN
R7
10MΩ
IREF 1
IC1
IC2
+In
FIGURE 4. Two Circuit Techniques for Reducing Noise in
the Unipolar Mode.
R8
200kΩ Pot
IREF 2
λ
ISO100
VOUT
1MΩ
RF
100kΩ
–In
18
1µF
VOUT
100kΩ
15
16
1µF
7
IC2 (MIN)
8
3
ISO100
IIN
IC2 (MAX)
IIN
VOUT
ea
l
9
Id
17
Shift due
to R7 and R8.
18
Shift due to R5 and R6.
FIGURE 6. Adjusting the Unipolar Amplifier Errors at Zero
Input.
FIGURE 5. Circuit Techniques for Reducing Noise from the
Current Sources in the Bipolar Mode.
ISO100
10
R10
1MΩ
Optional Bipolar IOS Adjust.
R11
10MΩ
R1
RF
1MΩ
RIN
VIN
15
9.76kΩ RG
500Ω
Pot
R12
316kΩ
IC
15
+
RF
16
7
R13
10MΩ
8
3
ISO100
+In
9
λ
7
8
–
RSOURCE
3
ISO100
9
+
VOUT
+
–
17
VOUT = –VIN (RF /R1)
18
VIN(1)
–In
17
14
13
+V
NOTE: (1) Use postitive input voltage only, VIN >> 10µA x RSOURCE.
18
R14
100kΩ
FIGURE 10. Unipolar Inverting.
FIGURE 7. Adjusting the Bipolar Errors.
R1
BASIC CIRCUIT CONNECTIONS
15
+
RF
16
7
8
3
ISO100
9
RSOURCE
+
VOUT = –VIN (RF /R1)
–
17
18
VIN(1)
NOTE: (1) VIN >> 10µA x RSOURCE.
FIGURE 11. Bipolar Inverting.
APPLICATION INFORMATION
FIGURE 8. Unipolar Noninverting.
Shield
RIN
15
+
RF
16
7
+
Major points to consider when designing circuits with the
ISO100.
8
1. Input Common (pin 18) and –In (pin 17) should be
grounded through separate lines. The Input Common can
carry a large DC current and may cause feedback to the
signal input.
3
ISO100
VIN
The small size, low offset and drift, wide bandwidth, ultralow leakage, and low cost, make the ISO100 ideal for a
variety of isolation applications. The basic mode of
operation of the ISO100 will be determined by the type of
signal and application.
9
IIN
VOUT = IINRF
or
VOUT = VIN (RF /RIN)
–
17
2. Use shielded or twisted pair cable at the input for long
lines.
18
3. Care should be taken to minimize external capacitance
across the isolation barrier.
FIGURE 9. Bipolar Noninverting.
11
ISO100
4. The distance across the isolation barrier, between
external components and conductor patterns, should be
maximized to reduce leakage and arcing.
CF may be used to
improve frequency
response (reduce peaking).
fO = 1/2π RFCF
Isolation Barrier
5. Although not an absolute requirement, the use of
conformally-coated printed circuit boards is recommended.
CF
0.02µA
to
10µA
6. When in the unipolar mode, the reference currents (pins
8 and 16) must be terminated. IIN should be greater than
20nA to keep internal LED on.
16
RF 1MΩ
15
+
7
Photodiode
7. The noise contribution of the reference currents will cause
the bipolar mode to be noisier than the unipolar mode.
8. The maximum output voltage swing is determined by IIN
and RF.
VSWING = IIN MAX X RF
3
2
9
VO = IINRF
4 C2
0.001µF
–
17
9. A capacitor (about 3pF) can be connected across RF to
compensate for peaking in the frequency response. The
peaking is caused by the pole generated by RF and the
capacitance at the input of the output amplifier.
8
ISO100
10
0 to –10V
12
18
C3
0.001µF
R2
15kΩ
R3
15kΩ
Figure 12 through 18 show applications of the ISO100.
+V
C
–V
C
–V
+V
p+
R1
1.2kΩ
+15V
722
V+
E
V–
Isolated
Power
Supply
C1
0.47µF
R3 and R2 are required to maintain
a 3mA minimum load to the 722.
FIGURE 12. Two-Port Isolation Photodiode Amplifier
Unipolar.
R2
50kΩ
Bridge
Excitation
VREF = +1V
6
Sensor
Tranducer
R
–
CF
2
IREF 1
OPA177
3
+
RF
1MΩ
15
+
+
1
R
(2)
16
R
10
R
R3
50kΩ
∆VIN
(3)
RG
404Ω
INA101
X 100
4
5
–
8
R1
100kΩ
7
7
9
6
9
–
8
ISO100
X 10
+
4
VOUT
2
–
17
10
+15V –15V
12
18
Total Gain = 1000
Input Common
Output
Common
(1)
+15V
–15V
NOTES: (1) For isolated supplies see Figure 12. (2) In this
example, the internal precision current reference, IREF, provides bridge
excitation. (3) Pin 8 of the INA101 must be more negative than –2mV
for linear operation of the ISO100 with R1 = 100kΩ.
FIGURE 13. Precision Bridge Isolation Amplifier (Unipolar).
ISO100
12
CF may be used to
improve frequency
response (reduce peaking).
fO = 1/2π RFCF
Isolation Barrier
Offsetting
CF
R4
1kΩ
R4
100kΩ
RF 1MΩ
16
–15V
15
+
7
Thermocouple
V = 10mV
(±Temp)
8
R2
1kΩ
3
2
9
VO = IINRF
4 C2
0.001µF
17
10
R1
100kΩ
+
(±10V)
RF
1MΩ
16
15
+
7
VIN
C3
0.001µF
VOUT
–
17
18
15kΩ
–V
C
–V
+V
p+
R1
1.2kΩ
+15V
722
Cold junction
compensation
not shown.
3
9
R2
15kΩ
R3
+V
C
8
ISO100
12
18
CF
R3
2MΩ
Gain
Adjust
ISO100
–
+15V
V+
E
V–
Isolated
Power
Supply
Gain = +10 to +1000
C1
0.47µF
Approximate input offsetting = 0 to ±7.5µA for
isolated supplies—see Figures 10 and 11.
R3 and R2 are required to maintain
a 3mA minimum load to the 722.
FIGURE 14. Three-Port Isolation Thermocouple Amplifier
(Bipolar).
R1
1MΩ
R2
500kΩ
Input
–5V to 0V
Offset
Adjust
16
+VISOLATED
15
RIN
500Ω
FIGURE 15. Isolated Test Equipment Amplifier (Unipolar
with Offsetting).
+
7
Span Adjust
2
ISO100
9
+
4
–
17
18
IOUT
4-20mA
8
–
3
RL
Siliconix
VN88AF
R4
335kΩ
–VISOLATED
For isolated supplies see Figures 10 and 11.
R3
200Ω
Calibration procedure:
1. Set VIN = 0V
2. Adjust R2 for IOUT = 20mA
3. Set VIN = –5V
4. Adjust RIN for IOUT = 4mA
FIGURE 16. Isolated 4mA to 20mA Transmitter (Example of an isolated voltage controlled current source).
13
ISO100
+VCC
RF
1MΩ
Offset Adjust
1MΩ
RIN
10kΩ
VIN 1
+15V
13
Offset Adjust
14
15
+
7
9
5
1MΩ
–
6 3
4
+
VOUT
2
–
Com 1 17
+15V –15V
(Non ISO)
+VCC
100kΩ
VIN 2
–VCC
VO = 1M [
15
+
7
9
VIN 2
VIN 1
+
+ IIN 1 +IIN 2]
10k
100k
–
(1)
+
–
Com 2 17
+VCC
–VCC
15
+
IIN 1
7
9
–
(1)
+
–
Com 3 17
+VCC
±VCCs
to input stages
of amplifiers
–VCC
1
15
+
IIN 2
7
9
2
3
–
(1)
+
724 Isolated
Power Supply
–
Com 4 17
+VCC
–VCC
+15V
(Non ISO)
NOTE: (1) No additional connections to output amplifiers
Note that a variety of input/gain configurations can be used.
FIGURE 17. Four-Port Isolated Summing Amplifier (Unipolar).
ISO100
14
4
Channel Select
OPTO
Isolator
Gain Select
CP
CE
IN7
CF
IN6
IN5
Input
Channels
16
IN4
IN3
1MΩ
PGA100
Analog P/S
IN2
IN1
IN0
15
+
RF
1MΩ
7
Digital
P/S
8
3
ISO100
4
9
2
–
17
VOUT
12
18
10
+5V
+15V
Input
Common(1)
–15V
Output
Common(1)
+15V –15V
NOTE: (1) For isolated power supplies see Figures 10 and 11.
FIGURE 18. Multiple Channel Isolation Amplifier (Bipolar) with Programmable Gain (useful in data acquisition systems).
15
ISO100
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