AD AD524AR-16

Precision
Instrumentation Amplifier
AD524
FEATURES
FUNCTIONAL BLOCK DIAGRAM
– INPUT 1
G = 10 13
G = 100 12
G = 1000 11
PROTECTION
AD524
4.44kΩ
404Ω
40Ω
Vb
RG1 16
20kΩ
20kΩ
20kΩ
20kΩ
SENSE
OUTPUT
RG2 3
+ INPUT 2
20kΩ
20kΩ
REFERENCE
00500-001
Low noise: 0.3 μV p-p at 0.1 Hz to 10 Hz
Low nonlinearity: 0.003% (G = 1)
High CMRR: 120 dB (G = 1000)
Low offset voltage: 50 μV
Low offset voltage drift: 0.5 μV/°C
Gain bandwidth product: 25 MHz
Pin programmable gains of 1, 10, 100, 1000
Input protection, power-on/power-off
No external components required
Internally compensated
MIL-STD-883B and chips available
16-lead ceramic DIP and SOIC packages and 20-terminal
leadless chip carrier available
Available in tape and reel in accordance with EIA-481A
standard
Standard military drawing also available
PROTECTION
Figure 1.
GENERAL DESCRIPTION
The AD524 is a precision monolithic instrumentation amplifier
designed for data acquisition applications requiring high accuracy under worst-case operating conditions. An outstanding
combination of high linearity, high common-mode rejection,
low offset voltage drift, and low noise makes the AD524 suitable
for use in many data acquisition systems.
higher linearity C grade are specified from −25°C to +85°C.
The S grade guarantees performance to specification over the
extended temperature range −55°C to +125°C. The AD524 is
available in a 16-lead ceramic DIP, 16-lead SBDIP, 16-lead SOIC
wide packages, and 20-terminal leadless chip carrier.
The AD524 has an output offset voltage drift of less than
25 μV/°C, input offset voltage drift of less than 0.5 μV/°C, CMR
above 90 dB at unity gain (120 dB at G = 1000), and maximum
nonlinearity of 0.003% at G = 1. In addition to the outstanding
dc specifications, the AD524 also has a 25 kHz bandwidth
(G = 1000). To make it suitable for high speed data acquisition
systems, the AD524 has an output slew rate of 5 V/μs and settles
in 15 μs to 0.01% for gains of 1 to 100.
1.
The AD524 has guaranteed low offset voltage, offset
voltage drift, and low noise for precision high gain
applications.
2.
The AD524 is functionally complete with pin programmable gains of 1, 10, 100, and 1000, and single resistor
programmable for any gain.
3.
Input and output offset nulling terminals are provided for
very high precision applications and to minimize offset
voltage changes in gain ranging applications.
4.
The AD524 is input protected for both power-on and
power-off fault conditions.
5.
The AD524 offers superior dynamic performance with a
gain bandwidth product of 25 MHz, full power response of
75 kHz and a settling time of 15 μs to 0.01% of a 20 V step
(G = 100).
As a complete amplifier, the AD524 does not require any external components for fixed gains of 1, 10, 100 and 1000. For other
gain settings between 1 and 1000, only a single resistor is required.
The AD524 input is fully protected for both power-on and
power-off fault conditions.
The AD524 IC instrumentation amplifier is available in four
different versions of accuracy and operating temperature range.
The economical A grade, the low drift B grade, and lower drift,
PRODUCT HIGHLIGHTS
Rev. F
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2007 Analog Devices, Inc. All rights reserved.
AD524
TABLE OF CONTENTS
Features .............................................................................................. 1
Input Offset and Output Offset ................................................ 15
Functional Block Diagram .............................................................. 1
Gain .............................................................................................. 16
General Description ......................................................................... 1
Input Bias Currents .................................................................... 17
Product Highlights ........................................................................... 1
Common-Mode Rejection ........................................................ 17
Revision History ............................................................................... 2
Grounding ................................................................................... 18
Specifications..................................................................................... 3
Sense Terminal............................................................................ 18
Absolute Maximum Ratings............................................................ 8
Reference Terminal .................................................................... 18
Connection Diagrams .................................................................. 8
Programmable Gain ................................................................... 20
ESD Caution .................................................................................. 8
Autozero Circuits ....................................................................... 20
Typical Performance Characteristics ............................................. 9
Error Budget Analysis ................................................................ 21
Test Circuits ................................................................................. 14
Outline Dimensions ....................................................................... 24
Theory of Operation ...................................................................... 15
Ordering Guide .......................................................................... 25
Input Protection.......................................................................... 15
REVISION HISTORY
11/07—Rev. E to Rev. F
Updated Format .................................................................. Universal
Changes to General Description .................................................... 1
Changes to Figure 1 .......................................................................... 1
Changes to Figure 3 and Figure 4 Captions .................................. 8
Changes to Error Budget Analysis Section ................................. 21
Changes to Ordering Guide .......................................................... 25
4/99—Rev. D to Rev. E
Rev. F | Page 2 of 28
AD524
SPECIFICATIONS
@ VS = ±15 V, RL = 2 kΩ and TA = +25°C, unless otherwise noted.
All min and max specifications are guaranteed. Specifications shown in boldface are tested on all production units at the final electrical
test. Results from those tests are used to calculate outgoing quality levels.
Table 1.
Parameter
GAIN
Gain Equation (External Resistor Gain Programming)
Gain Range (Pin Programmable)
Gain Error 1
G=1
G = 10
G = 100
G = 1000
Nonlinearity
G=1
G = 10, G = 100
G = 1000
Gain vs. Temperature
G=1
G = 10
G = 100
G = 1000
VOLTAGE OFFSET (May be Nulled)
Input Offset Voltage
vs. Temperature
Output Offset Voltage
vs. Temperature
Offset Referred to the Input vs. Supply
G=1
G = 10
G = 100
G = 1000
INPUT CURRENT
Input Bias Current
vs. Temperature
Input Offset Current
vs. Temperature
Min
AD524A
Typ
Max
Min
AD524B
Typ
Max
⎡ 40 ,000 ⎤
+ 1⎥ ± 20%
⎢
⎣ RG
⎦
⎡ 40 ,000 ⎤
+ 1⎥ ± 20%
⎢
⎣ RG
⎦
1 to 1000
1 to 1000
±0.05
±0.25
±0.5
±2.0
±0.03
±0.15
±0.35
±1.0
%
%
%
%
±0.01
±0.01
±0.01
±0.005
±0.005
±0.01
%
%
%
5
15
35
100
5
10
25
50
ppm/°C
ppm/°C
ppm/°C
ppm/°C
250
2
5
100
100
0.75
3
50
μV
μV/°C
mV
μV
70
85
95
100
dB
dB
dB
dB
75
95
105
110
±50
±100
±25
±100
±35
±100
Rev. F | Page 3 of 28
Unit
±15
±100
nA
pA/°C
nA
pA/°C
AD524
Parameter
INPUT
Input Impedance
Differential Resistance
Differential Capacitance
Common-Mode Resistance
Common-Mode Capacitance
Input Voltage Range
Maximum Differential Input Linear (VDL) 2
Maximum Common-Mode Linear (VCM)2
Min
AD524A
Typ
Max
Min
109
10
109
10
±10
Unit
109
10
109
10
Ω
pF
Ω
pF
±10
⎛G
⎞
12 V − ⎜ × VD ⎟
2
⎝
⎠
Common-Mode Rejection DC to 60 Hz with 1 kΩ Source Imbalance
G=1
G = 10
G = 100
G = 1000
OUTPUT RATING
VOUT, RL = 2 kΩ
DYNAMIC RESPONSE
Small Signal – 3 dB
G=1
G = 10
G = 100
G = 1000
Slew Rate
Settling Time to 0.01%, 20 V Step
G = 1 to 100
G = 1000
NOISE
Voltage Noise, 1 kHz
RTI
RTO
RTI, 0.1 Hz to 10 Hz
G=1
G = 10
G = 100, 1000
Current Noise
0.1 Hz to 10 Hz
SENSE INPUT
RIN
IIN
Voltage Range
Gain to Output
REFERENCE INPUT
RIN
IIN
Voltage Range
Gain to Output
AD524B
Typ
Max
70
90
100
110
V
dB
dB
dB
dB
75
95
105
115
±10
±10
V
1
400
150
25
5.0
1
400
150
25
5.0
MHz
kHz
kHz
kHz
V/μs
15
75
15
75
μs
μs
7
90
7
90
nV/√Hz
nV√Hz
15
2
0.3
15
2
0.3
μV p-p
μV p-p
μV p-p
60
60
pA p-p
20
15
20
15
kΩ ± 20%
μA
V
%
±10
±10
1
1
40
15
40
15
±10
Rev. F | Page 4 of 28
⎛G
⎞
12 V − ⎜ × VD ⎟
2
⎝
⎠
V
V
±10
1
1
kΩ ± 20%
μA
V
%
AD524
Parameter
TEMPERATURE RANGE
Specified Performance
Storage
POWER SUPPLY
Power Supply Range
Quiescent Current
1
2
Min
AD524A
Typ
Max
Min
AD524B
Typ
Max
–25
–65
+85
+150
–25
–65
+85
+150
°C
°C
±18
5.0
±6
±18
5.0
V
mA
±15
3.5
±6
±15
3.5
Unit
Does not include effects of external resistor, RG.
VOL is the maximum differential input voltage at G = 1 for specified nonlinearity.
VDL at the maximum = 10 V/G.
VD = actual differential input voltage.
Example: G = 10, VD = 0.50.
VCM = 12 V − (10/2 × 0.50 V) = 9.5 V.
@ VS = ±15 V, RL = 2 kΩ and TA = +25°C, unless otherwise noted.
All min and max specifications are guaranteed. Specifications shown in boldface are tested on all production units at the final electrical
test. Results from those tests are used to calculate outgoing quality levels.
Table 2.
Parameter
GAIN
Gain Equation (External Resistor Gain Programming)
Gain Range (Pin Programmable)
Gain Error 1
G=1
G = 10
G = 100
G = 1000
Nonlinearity
G=1
G = 10, G = 100
G = 1000
Gain vs. Temperature
G=1
G = 10
G = 100
G = 1000
VOLTAGE OFFSET (May be Nulled)
Input Offset Voltage
vs. Temperature
Output Offset Voltage
vs. Temperature
Offset Referred to the Input vs. Supply
G=1
G = 10
G = 100
G = 1000
Min
AD524C
Typ
Max
Min
AD524S
Typ
Max
⎡ 40 ,000 ⎤
+ 1⎥ ± 20%
⎢
⎣ RG
⎦
⎡ 40 ,000 ⎤
+ 1⎥ ± 20%
⎢
⎣ RG
⎦
1 to 1000
1 to 1000
80
100
110
115
Rev. F | Page 5 of 28
Unit
±0.02
±0.1
±0.25
±0.5
±0.05
±0.25
±0.5
±2.0
%
%
%
%
±0.003
±0.003
±0.01
±0.01
±0.01
±0.01
%
%
%
5
10
25
50
5
10
25
50
ppm/°C
ppm/°C
ppm/°C
ppm/°C
50
0.5
2.0
25
100
2.0
3.0
50
μV
μV/°C
mV
μV
75
95
105
110
dB
dB
dB
dB
AD524
Parameter
INPUT CURRENT
Input Bias Current
vs. Temperature
Input Offset Current
vs. Temperature
INPUT
Input Impedance
Differential Resistance
Differential Capacitance
Common-Mode Resistance
Common-Mode Capacitance
Input Voltage Range
Maximum Differential Input Linear (VDL) 2
Maximum Common-Mode Linear (VCM)2
AD524C
Typ
Max
Min
Min
AD524S
Typ
Max
±100
±100
nA
pA/°C
nA
pA/°C
109
10
109
10
109
10
109
10
Ω
pF
Ω
pF
±15
±50
±100
±100
±10
±10
±35
±10
⎛G
⎞
12 V − ⎜ × VD ⎟
⎝2
⎠
Common-Mode Rejection DC to 60 Hz with 1 kΩ Source Imbalance
G=1
G = 10
G = 100
G = 1000
OUTPUT RATING
VOUT, RL = 2 kΩ
DYNAMIC RESPONSE
Small Signal – 3 dB
G=1
G = 10
G = 100
G = 1000
Slew Rate
Settling Time to 0.01%, 20 V Step
G = 1 to 100
G = 1000
NOISE
Voltage Noise, 1 kHz
RTI
RTO
RTI, 0.1 Hz to 10 Hz
G=1
G = 10
G = 100, 1000
Current Noise
0.1 Hz to 10 Hz
SENSE INPUT
RIN
IIN
Voltage Range
Gain to Output
80
100
110
120
⎛G
⎞
12 V − ⎜ × VD ⎟
⎝2
⎠
V
V
V
dB
dB
dB
dB
70
90
100
110
±10
±10
V
1
400
150
25
5.0
1
400
150
25
5.0
MHz
kHz
kHz
kHz
V/μs
15
75
15
75
μs
μs
7
90
7
90
nV/√Hz
nV√Hz
15
2
0.3
15
2
0.3
μV p-p
μV p-p
μV p-p
60
60
pA p-p
20
15
20
15
kΩ ± 20%
μA
V
%
±10
Rev. F | Page 6 of 28
Unit
±10
1
1
AD524
Parameter
REFERENCE INPUT
RIN
IIN
Voltage Range
Gain to Output
TEMPERATURE RANGE
Specified Performance
Storage
POWER SUPPLY
Power Supply Range
Quiescent Current
1
2
Min
AD524C
Typ
Max
Min
40
15
40
15
10
–25
–65
Does not include effects of external resistor RG.
VOL is the maximum differential input voltage at G = 1 for specified nonlinearity.
VDL at the maximum = 10 V/G.
VD = actual differential input voltage.
Example: G = 10, VD = 0.50.
VCM = 12 V − (10/2 × 0.50 V) = 9.5 V.
Rev. F | Page 7 of 28
±15
3.5
1
+85
+150
–55
–65
±18
5.0
±6
±15
3.5
Unit
kΩ ± 20%
μA
V
%
10
1
±6
AD524S
Typ
Max
+85
+150
°C
°C
±18
5.0
V
mA
AD524
ABSOLUTE MAXIMUM RATINGS
CONNECTION DIAGRAMS
– INPUT 1
16
RG1
+ INPUT 2
15
OUTPUT NULL
14
OUTPUT NULL
RG2 3
G = 10
TOP VIEW
INPUT NULL 5 (Not to Scale) 12 G = 100
<36 V
Indefinite
–65°C to +125°C
–65°C to +150°C
11
–VS 7
10
SENSE
+VS 8
9
OUTPUT
–25°C to +85°C
–55°C to +125°C
+300°C
14
+INPUT
2
–INPUT
NC
RG1
OUTPUT
NULL
+INPUT
20 19
18
OUTPUT NULL
17
G = 10
16
NC
15
G = 100
14
G = 1000
AD524
TOP VIEW
(Not to Scale)
10 11 12 13
7
19
INPUT
OFFSET NULL
5
18
SENSE
9
NC
NC = NO CONNECT
–VS
OUTPUT
OFFSET NULL
Figure 4. Leadless Chip Carrier (E)
ESD CAUTION
00500-002
6
REFERENCE
Figure 2. Metallization Photograph
Contact factory for latest dimensions;
Dimensions shown in inches and (mm)
Rev. F | Page 8 of 28
SHORT TO
RG2 FOR
DESIRED
GAIN
00500-004
INPUT NULL 7
REFERENCE 8
+VS
7 –VS
0.170 (4.33)
1
NC 6
RG2
3
PAD NUMBERS CORRESPOND TO PIN NUMBERS FOR
THE D-16 AND RW-16 16-LEAD CERAMIC PACKAGES.
2
RG2 4
0.103
(2.61)
–INPUT
1
3
INPUT NULL 5
SENSE
10
RG1 16
OUTPUT
OFFSET NULL
Figure 3. Ceramic (D) and
SOIC (RW-16 and D-16) Packages
8 +VS
5
INPUT
NULL
5
G = 1000
SHORT TO
RG2 FOR
DESIRED
GAIN
–VS
INPUT
OFFSET NULL
9
OUTPUT
4
INPUT
NULL
15
OUTPUT
G = 1000
11
4
+VS
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
G = 10 G = 100
13
12
13
REFERENCE 6
Maximum input voltage specification refers to maximum voltage to which
either input terminal may be raised with or without device power applied.
For example, with ±18 volt supplies maximum, VIN is ±18 V; with zero supply
voltage maximum, VIN is ±36 V.
OUTPUT
NULL
14
OUTPUT
NULL
15
AD524
INPUT NULL 4
–VS
1
Rating
±18 V
450 mW
+VS
Parameter
Supply Voltage
Internal Power Dissipation
Input Voltage1
(Either Input Simultaneously) |VIN| + |VS|
Output Short-Circuit Duration
Storage Temperature Range
(R)
(D, E)
Operating Temperature Range
AD524A/AD524B/AD524C
AD524S
Lead Temperature (Soldering, 60 sec)
00500-003
Table 3.
AD524
TYPICAL PERFORMANCE CHARACTERISTICS
8
INPUT VOLTAGE (±V)
15
10
+25°C
0
00500-005
5
0
5
10
SUPPLY VOLTAGE (±V)
15
6
4
2
0
20
00500-008
QUIESCENT CURRENT (mA)
20
0
Figure 5. Input Voltage Range vs. Supply Voltage, G = 1
5
10
SUPPLY VOLTAGE (±V)
15
20
Figure 8. Quiescent Current vs. Supply Voltage
20
16
INPUT BIAS CURRENT (±nA)
15
10
5
0
5
10
SUPPLY VOLTAGE (±V)
15
10
8
6
4
0
20
00500-009
0
12
2
00500-006
0
Figure 6. Output Voltage Swing vs. Supply Voltage
10
SUPPLY VOLTAGE (±V)
15
20
Figure 9. Input Bias Current vs. Supply Voltage
30
40
INPUT BIAS CURRENT (nA)
30
20
10
0
10
100
1k
LOAD RESISTANCE (Ω)
20
10
0
–10
–20
–30
00500-007
OUTPUT VOLTAGE SWING (V p-p)
5
–40
10k
Figure 7. Output Voltage Swing vs. Load Resistance
00500-010
OUTPUT VOLTAGE SWING (±V)
14
–75
–25
25
TEMPERATURE (°C)
75
Figure 10. Input Bias Current vs. Temperature
Rev. F | Page 9 of 28
125
AD524
16
–140
G = 1000
G = 100
–120
12
G = 10
–100
10
CMRR (dB)
8
6
–60
–40
4
–20
00500-011
2
0
G=1
–80
0
5
10
INPUT VOLTAGE (±V)
15
0
20
Figure 11. Input Bias Current vs. Input Voltage
00500-014
INPUT BIAS CURRENT (±nA)
14
0
10
100
1k
10k
100k
FREQUENCY (Hz)
1M
10M
Figure 14. CMRR vs. Frequency, RTI, Zero to 1000 Source Imbalance
30
1
2
3
4
5
00500-012
6
0
1
2
3
4
5
6
WARM-UP TIME (Minutes)
7
G = 1, 10, 100
20
10
BANDWIDTH LIMITED
G = 1000
0
1k
8
Figure 12. Offset Voltage, RTI, Turn-On Drift
G = 100
G = 10
10k
100k
FREQUENCY (Hz)
00500-015
FULL POWER RESPONSE (V p-p)
ΔVOS FROM FINAL VALUE (µV)
0
1M
Figure 15. Large Signal Frequency Response
10
8
SLEW RATE (V/µs)
100
10
6
4
G = 1000
1
0
10
100
1k
10k
100k
FREQUENCY (Hz)
1M
0
10M
Figure 13. Gain vs. Frequency
00500-016
2
00500-013
GAIN (V/V)
1000
1
10
GAIN (V/V)
100
Figure 16. Slew Rate vs. Gain
Rev. F | Page 10 of 28
1000
AD524
140
120
G=
1000
G=
100
100
80
G=
60
G=
10
1
40
20
0
10
100
1k
FREQUENCY (Hz)
10k
10k
1k
100
00500-020
CURRENT NOISE SPECTRAL DENSITY (fA/ Hz)
100k
+VS = 15V DC +
1V p-p SINEWAVE
00500-017
1
0
100k
Figure 17. Positive PSRR vs. Frequency
1k
10k
0.1Hz TO 10Hz
–VS = –15V DC +
1V p-p SINEWAVE
140
5mV
1s
120
G=
80
1000
100
G=
10
G=
1
60
40
20
0
10
100
1k
FREQUENCY (Hz)
10k
100k
VERTICAL SCALE; 1 DIVISION = 5µV
Figure 18. Negative PSRR vs. Frequency
00500-021
G=
100
00500-018
POWER SUPPLY REJECTION RATIO (dB)
100
Figure 20. Input Current Noise vs. Frequency
160
Figure 21. Low Frequency Noise, G = 1 (System Gain = 1000)
1000
0.1Hz TO 10Hz
10mV
1s
G=1
100
G = 10
10
G = 100, 1000
G = 1000
1
0.1
00500-019
VOLT NSD (nV/ Hz)
10
FREQUENCY (Hz)
1
10
100
1k
10k
100k
VERTICAL SCALE; 1 DIVISION = 0.1µV
FREQUENCY (Hz)
Figure 19. RTI Noise Spectral Density vs. Gain
00500-022
POWER SUPPLY REJECTION RATIO (dB)
160
Figure 22. Low Frequency Noise, G = 1000 (System Gain = 100,000)
Rev. F | Page 11 of 28
AD524
–12 TO +12
1%
0.1%
0.01%
–8 TO +8
1mV
10V
10µs
–4 TO +4
OUTPUT
STEP (V)
+4 TO –4
+8 TO –8
1%
0.1%
0.01%
00500-023
+12 TO –12
5
10
15
20
00500-026
0
SETTLING TIME (µs)
Figure 23. Settling Time, Gain = 1
Figure 26. Large Signal Pulse Response and Settling Time, Gain = 10
–12 TO +12
0.1%
1%
1mV
10V
0.01%
–8 TO +8
10µs
–4 TO +4
OUTPUT
STEP (V)
+4 TO –4
+8 TO –8
0.01%
1%
00500-024
0
5
00500-027
0.1%
+12 TO –12
10
15
20
SETTLING TIME (µs)
Figure 24. Large Signal Pulse Response and Settling Time, Gain =1
Figure 27. Settling Time, Gain = 100
–12 TO +12
1%
0.1%
0.01%
–8 TO +8
1mV
10V
10µs
–4 TO +4
OUTPUT
STEP (V)
+4 TO –4
+8 TO –8
1%
0.1%
0.01%
0
5
10
15
00500-028
00500-025
+12 TO –12
20
SETTLING TIME (µs)
Figure 25. Settling Time, Gain = 10
Figure 28. Large Signal Pulse Response and Settling Time, Gain = 100
Rev. F | Page 12 of 28
AD524
–12 TO +12
0.1%
1%
0.01%
–8 TO +8
5mV
10V
20µs
–4 TO +4
OUTPUT
STEP (V)
+4 TO –4
+8 TO –8
0.1%
1%
0.01%
0
10
20
30
40
50
60
70
00500-030
00500-029
+12 TO –12
80
SETTLING TIME (µs)
Figure 29. Settling Time, Gain = 1000
Figure 30. Large Signal Pulse Response and Settling Time, Gain = 1000
Rev. F | Page 13 of 28
AD524
TEST CIRCUITS
10kΩ
0.01%
100kΩ
0.1%
G = 10
G = 100
1kΩ
0.1%
VOUT
+VS
RG1
11kΩ
0.1%
10kΩ
0.1%
100Ω
0.1%
G = 1000
RG2
1
–
8
16
13
10
AD524
12
3
2
9
6
11
7
+
00500-031
INPUT
20V p-p
1kΩ
10T
–VS
Figure 31. Settling Time Test Circuit
+VS
A1
+
–IN
CH2,
CH3, CH4
CH1
R57
20kΩ
Q1, Q3
R52
20kΩ
A2
C3
RG1
I3
50µA
I2
50µA
VB
C4
R53
20kΩ
+
A3
R56
20kΩ
4.44kΩ
404Ω
40Ω
R54
20kΩ
Q2, Q4
CH2, CH3,
CH4
RG2
G = 100
G = 1000
R55
20kΩ
I4
50µA
SENSE
VO
REFERENCE
+IN
CH1
–VS
Figure 32. Simplified Circuit of Amplifier; Gain Is Defined as
((R56 + R57)/(RG)) +1; For a Gain of 1, RG Is an Open Circuit
Rev. F | Page 14 of 28
00500-032
I1
50µA
AD524
THEORY OF OPERATION
from excessive currents. Standard practice is to place series
limiting resistors in each input, but to limit input current to
below 5 mA with a full differential overload (36 V) requires
over 7kΩ of resistance, which adds 10 nV√Hz of noise. To
provide both input protection and low noise, a special series
protection FET is used.
The AD524 is a monolithic instrumentation amplifier based
on the classic 3-op amp circuit. The advantage of monolithic
construction is the closely matched components that enhance
the performance of the input preamplifier. The preamplifier
section develops the programmed gain by the use of feedback
concepts. The programmed gain is developed by varying the
value of RG (smaller values increase the gain) while the feedback
forces the collector currents (Q1, Q2, Q3, and Q4) to be constant,
which impresses the input voltage across RG.
A unique FET design was used to provide a bidirectional
current limit, thereby protecting against both positive and
negative overloads. Under nonoverload conditions, three
channels (CH2, CH3, CH4) act as a resistance (≈1 kΩ) in series
with the input as before. During an overload in the positive
direction, a fourth channel, CH1, acts as a small resistance
(≈3 kΩ) in series with the gate, which draws only the leakage
current, and the FET limits IDSS. When the FET enhances under
a negative overload, the gate current must go through the small
FET formed by CH1 and when this FET goes into saturation,
the gate current is limited and the main FET goes into controlled
enhancement. The bidirectional limiting holds the maximum
input current to 3 mA over the 36 V range.
As RG is reduced to increase the programmed gain, the
transconductance of the input preamplifier increases to the
transconductance of the input transistors. This has three
important advantages. First, this approach allows the circuit
to achieve a very high open-loop gain of 3 × 108 at a programmed
gain of 1000, thus reducing gain-related errors to a negligible
30 ppm. Second, the gain bandwidth product, which is determined by C3 or C4 and the input transconductance, reaches
25 MHz. Third, the input voltage noise reduces to a value
determined by the collector current of the input transistors
for an RTI noise of 7 nV/√Hz at G = 1000.
INPUT OFFSET AND OUTPUT OFFSET
INPUT PROTECTION
Voltage offset specifications are often considered a figure of
merit for instrumentation amplifiers. While initial offset may
be adjusted to zero, shifts in offset voltage due to temperature
variations causes errors. Intelligent systems can often correct
this factor with an autozero cycle, but there are many smallsignal high-gain applications that do not have this capability.
As interface amplifiers for data acquisition systems, instrumentation amplifiers are often subjected to input overloads,
that is, voltage levels in excess of the full scale for the selected
gain range. At low gains (10 or less), the gain resistor acts as a
current limiting element in series with the inputs. At high gains,
the lower value of RG does not adequately protect the inputs
+VS
10
100
–
16
8
13
AD524
12
1000
11
RG2
2
16.2kΩ
9
1µF
+
3 +
1/2
2 –
6
3
AD712
+Vs
10
1µF
8
5 +
1
9.09kΩ
7
1/2
6 –
1µF
G = 1, 10, 100
–VS
G = 1000
7
4
1kΩ
100Ω
Figure 33. Noise Test Circuit
Rev. F | Page 15 of 28
16.2kΩ
–VS
1.62MΩ
1.82kΩ
00500-033
1
AD524
By separating these errors, one can evaluate the total error
independent of the gain setting used. In a given gain configuration, both errors can be combined to give a total error referred
to the input (RTI) or output (RTO) by the following formulas:
The AD524 can be configured for gains other than those that
are internally preset; there are two methods to do this. The first
method uses just an external resistor connected between
Pin 3 and Pin 16 (see Figure 35), which programs the gain
according to the following formula:
RG =
40 kΩ
G = −1
For best results, RG should be a precision resistor with a low
temperature coefficient. An external RG affects both gain
accuracy and gain drift due to the mismatch between it and
the internal thin-film resistors. Gain accuracy is determined
by the tolerance of the external RG and the absolute accuracy
of the internal resistors (±20%). Gain drift is determined by the
mismatch of the temperature coefficient of RG and the temperature coefficient of the internal resistors (−50 ppm/°C typical).
+VS
–INPUT
Total error RTI = input error + (output error/gain)
1
RG1
1.5kΩ
Total error RTO = (gain × input error) + output error
2.105kΩ
RG2
The second method uses the internal resistors in parallel with
an external resistor (see Figure 36). This technique minimizes
the gain adjustment range and reduces the effects of temperature coefficient sensitivity.
+VS
1
G = 10
13
G = 100
12
G = 1000
11
RG2
3
4kΩ
RG2
+INPUT
10kΩ
5
AD524
7
2
8
13
12
10
AD524
6
11
INPUT
OFFSET
NULL
4
16
G = 10
3
–VS
VOUT
REFERENCE
7
2
*R| G = 10 = 4444.44Ω
*R|G = 100 = 404.04Ω
*R|G = 1000 = 40.04Ω
*NOMINAL (±20%)
9
G=
40,000
+ 1 = 20 ±17%
4000||4444.44
Figure 36. Operating Connections for G = 20, Low Gain
Temperature Coefficient Technique
10
6
9
VOUT
OUTPUT
SIGNAL
COMMON
–VS
00500-034
+INPUT
16
REFERENCE
40,000
G=
+ 1 = 20 ±20%
2.105
Figure 34. Operating Connections for G = 100
Rev. F | Page 16 of 28
00500-036
The AD524 has internal high accuracy pretrimmed resistors
for pin programmable gains of 1, 10, 100, and 1000. One of the
preset gains can be selected by pin strapping the appropriate
gain terminal and RG2 together (for G = 1, RG2 is not connected).
RG1
VOUT
Figure 35. Operating Connections for G = 20
RG1
8
9
6
7
–VS
GAIN
1
3
2
–INPUT
–INPUT
10
AD524
11
+INPUT
The AD524 provides for both input and output offset adjustment.
This simplifies very high precision applications and minimizes
offset voltage changes in switched gain applications. In such
applications, the input offset is adjusted first at the highest
programmed gain, then the output offset is adjusted at G = 1.
+VS
12
1kΩ
As an illustration, a typical AD524 might have a +250 μV
output offset and a −50 μV input offset. In a unity gain
configuration, the total output offset would be 200 μV or
the sum of the two. At a gain of 100, the output offset would
be −4.75 mV or: +250 μV + 100(−50 μV) = −4.75 mV.
8
16
13
00500-035
Voltage offset and drift comprise two components each; input
and output offset and offset drift. Input offset is the component
of offset that is directly proportional to gain, that is, input offset
as measured at the output at G = 100 is 100 times greater than at
G = 1. Output offset is independent of gain. At low gains, output
offset drift is dominant, at high gains, input offset drift dominates.
Therefore, the output offset voltage drift is normally specified as
drift at G = 1 (where input effects are insignificant), whereas
input offset voltage drift is given by drift specification at a high
gain (where output offset effects are negligible). All input
related numbers are referred to the input (RTI) that is the effect
on the output is G times larger. Voltage offset vs. power supply
is also specified at one or more gain settings and is also RTI.
AD524
+VS
+VS
G = 10
13
G = 100
12
G = 1000
11
RG2
3
+INPUT
G=
10
AD524
9
6
R2
5kΩ
VOUT
RL
2
(R2||40kΩ) + R1 + R3
(R2||40kΩ)
–VS
(R1 + R2 + R3)||RL ≥ 2kΩ
Figure 37. Gain of 2000
Table 4. Output Gain Resistor Values
Output Gain
2
5
10
R2
5 kΩ
1.05 kΩ
1 kΩ
Nominal Gain
2.02
5.01
10.1
Input bias currents are those currents necessary to bias the
input transistors of a dc amplifier. Bias currents are an
additional source of input error and must be considered in
a total error budget. The bias currents, when multiplied by
the source resistance, appear as an offset voltage. What is of
concern in calculating bias current errors is the change in bias
current with respect to signal voltage and temperature. Input
offset current is the difference between the two input bias
currents. The effect of offset current is an input offset voltage
whose magnitude is the offset current times the source
impedance imbalance.
+VS
+
AD524
Common-mode rejection is a measure of the change in output
voltage when both inputs are changed equal amounts. These
specifications are usually given for a full-range input voltage
change and a specified source imbalance. Common-mode
rejection ratio (CMRR) is a ratio expression whereas commonmode rejection (CMR) is the logarithm of that ratio. For
example, a CMRR of 10,000 corresponds to a CMR of 80 dB.
In an instrumentation amplifier, ac common-mode rejection is
only as good as the differential phase shift. Degradation of ac
common-mode rejection is caused by unequal drops across
differing track resistances and a differential phase shift due
to varied stray capacitances or cable capacitances. In many
applications, shielded cables are used to minimize noise. This
technique can create common-mode rejection errors unless the
shield is properly driven. Figure 41 and Figure 42 show active
data guards that are configured to improve ac common-mode
rejection by bootstrapping the capacitances of the input cabling,
thus minimizing differential phase shift.
–INPUT
9
G = 100
6
100Ω
7
–
RG2
LOAD
AD711
–VS
TO POWER
SUPPLY
GROUND
00500-038
16
3
11
1
–
7
–VS
10
AD524
3
2
9
VOUT
6
REFERENCE
7
+
+VS
100Ω
AD712
1
RG1
–
8
16
10
10
9
AD524
12
LOAD
100Ω
TO POWER
SUPPLY
GROUND
9
RG2
3
2
+
7
–VS
Figure 42. Differential Shield Driver
Figure 39. Indirect Ground Returns for Bias Currents—Thermocouple
Rev. F | Page 17 of 28
VOUT
6
–VS
+INPUT
00500-039
16
8
12
6
13
–
–INPUT
8
AD524
12
+INPUT
1
Figure 41. Shield Driver, G ≥ 100
+VS
+
+VS
–VS
Figure 38. Indirect Ground Returns for Bias Currents—Transformer Coupled
2
TO POWER
SUPPLY
GROUND
Although instrumentation amplifiers have differential inputs,
there must be a return path for the bias currents. If this is not
provided, those currents charge stray capacitances, causing the
output to drift uncontrollably or to saturate. Therefore, when
amplifying floating input sources such as transformers and
thermocouples, as well as ac-coupled sources, there must still
be a dc path from each input to ground.
10
13
1
–VS
8
3
11
12
LOAD
7
–
1
COMMON-MODE REJECTION
R1, R3
2.26 kΩ
2.05 kΩ
4.42 kΩ
INPUT BIAS CURRENTS
2
16
Figure 40. Indirect Ground Returns for Bias Currents–AC-Coupled
R3
2.26kΩ
7
9
6
13
R1
2.26kΩ
8
10
AD524
12
00500-041
16
8
3
11
REFERENCE
00500-042
1
RG1
00500-037
–INPUT
+
2
00500-040
The AD524 can also be configured to provide gain in the output
stage. Figure 37 shows an H pad attenuator connected
to the reference and sense lines of the AD524. R1, R2, and R3
should be made as low as possible to minimize the gain variation
and reduction of CMRR. Varying R2 precisely sets the gain
without affecting CMRR. CMRR is determined by the match
of R1 and R3.
AD524
GROUNDING
SENSE TERMINAL
Many data acquisition components have two or more ground
pins that are not connected together within the device. These
grounds must be tied together at one point, usually at the system
power-supply ground. Ideally, a single solid ground would be
desirable. However, because current flows through the ground
wires and etch stripes of the circuit cards, and because these
paths have resistance and inductance, hundreds of millivolts can
be generated between the system ground point and the data
acquisition components. Separate ground returns should be
provided to minimize the current flow in the path from the
sensitive points to the system ground point. In this way, supply
currents and logic-gate return currents are not summed into the
same return path as analog signals where they would cause
measurement errors.
The sense terminal is the feedback point for the instrument
amplifier’s output amplifier. Normally, it is connected to the
instrument amplifier output. If heavy load currents are to be
drawn through long leads, voltage drops due to current flowing
through lead resistance can cause errors. The sense terminal can
be wired to the instrument amplifier at the load, thus putting
the IxR drops inside the loop and virtually eliminating this
error source.
DIG
COM
8
7
2
AD524
1
6
OUTPUT
REFERENCE
1µF 1µF
10
9
AD583
SAMPLE
AND HOLD
ANALOG
GROUND*
7
9
1µF
11 15
AD574A
1
DIGITAL
DATA
OUTPUT
SIGNAL
GROUND
*IF INDEPENDENT; OTHERWISE, RETURN AMPLIFIER REFERENCE
TO MECCA AT ANALOG P.S. COMMON.
Figure 43. Basic Grounding Practice
3
10
AD524
1
9
6
12
VIN–
OUTPUT
CURRENT
BOOSTER
8
7
V–
DIGITAL P.S.
+5V
C
0.1 0.1
µF µF
0.1 0.1
µF µF
2
(REF)
X1
RL
Figure 44. AD524 Instrumentation Amplifier with Output Current Booster
00500-043
ANALOG P.S.
+15V C –15V
VIN+
(SENSE)
00500-044
Because the output voltage is developed with respect to the
potential on the reference terminal, an instrumentation
amplifier can solve many grounding problems.
V+
Typically, IC instrumentation amplifiers are rated for a full
±10 volt output swing into 2 kΩ. In some applications, however,
the need exists to drive more current into heavier loads.
Figure 44 shows how a high current booster may be connected
inside the loop of an instrumentation amplifier to provide the
required current boost without significantly degrading overall
performance. Nonlinearities and offset and gain inaccuracies of
the buffer are minimized by the loop gain of the AD524 output
amplifier. Offset drift of the buffer is similarly reduced.
REFERENCE TERMINAL
The reference terminal can be used to offset the output by up to
±10 V. This is useful when the load is floating or does not share
a ground with the rest of the system. It also provides a direct
means of injecting a precise offset. It must be remembered that
the total output swing is ±10 V to be shared between signal and
reference offset.
When the AD524 is of the 3-amplifier configuration it
is necessary that nearly zero impedance be presented to the
reference terminal.
Any significant resistance from the reference terminal to
ground increases the gain of the noninverting signal path,
thereby upsetting the common-mode rejection of the AD524.
In the AD524, a reference source resistance unbalances the CMR
trim by the ratio of 20 kΩ/RREF. For example, if the reference
source impedance is 1 Ω, CMR is reduced to 86 dB (20 kΩ/1 Ω
= 86 dB). An operational amplifier can be used to provide that
low impedance reference point, as shown in Figure 45. The
input offset voltage characteristics of that amplifier adds directly
to the output offset voltage performance of the instrumentation
amplifier.
Rev. F | Page 18 of 28
AD524
+VS
8
R1
AD524
9
9
–INPUT
LOAD
REF
1
IL
VX
13
6
7
1
10
3
AD524
12
SENSE
+
2
10
3
6
–
REF
A2
–VS
VOFFSET
AD711
AD711
IL =
VX
R1
=
VIN
R1
(
= 1+
40,000
RG
Figure 45. Use of Reference Terminal to Provide Output Offset
LOAD
)
00500-046
VIN–
+INPUT
SENSE
2
00500-045
VIN+
Figure 46. Voltage-to-Current Converter
An instrumentation amplifier can be turned into a voltageto-current converter by taking advantage of the sense and
reference terminals, as shown in Figure 46.
By establishing a reference at the low side of a current setting
resistor, an output current may be defined as a function of input
voltage, gain, and the value of that resistor. Because only a small
current is demanded at the input of the buffer amplifier (A2)
the forced current, IL, largely flows through the load. Offset and
drift specifications of A2 must be added to the output offset and
drift specifications of the AD524.
–IN
1
PROTECTION
16
+IN
2
PROTECTION
15
+VS
3
INPUT
OFFSET
TRIM
R1
10kΩ
4
20kΩ
–VS
7
+VS
8
20kΩ
20kΩ
404Ω
20kΩ
40Ω
20kΩ
A1
AD524
13
NC
G = 100
K2
G = 10
K1
G = 1000
K3
RELAY
SHIELDS
12
11
+5V
10
9
K1
OUT
D1
K2
D2
K3
D3
C2
K1 – K3 =
THERMOSEN DM2C
4.5V COIL
D1 – D3 = IN4148
GAIN TABLE
A B GAIN
0 0 10
0 1 1000
1 0 100
1 1 1
INPUTS A
GAIN
RANGE B
1
16
2
15
Y0
Y1
74LS138 14 Y2
DECODER
13
4
3
+5V
2
3
4
5
5
6
6
7
7
NC = NO CONNECT
Figure 47. Three-Decade Gain Programmable Amplifier
Rev. F | Page 19 of 28
16
1
7407N
BUFFER
DRIVER
10µF
LOGIC
COMMON
00500-047
ANALOG
COMMON
C1
20kΩ
5
6
1µF
35V
14
4.44kΩ
R2
10kΩ
OUTPUT
OFFSET
TRIM
AD524
PROGRAMMABLE GAIN
Figure 47 shows the AD524 being used as a software programmable gain amplifier. Gain switching can be accomplished with
mechanical switches such as DIP switches or reed relays. It should
be noted that the on resistance of the switch in series with the
internal gain resistor becomes part of the gain equation and has
an effect on gain accuracy.
The AD524 can also be connected for gain in the output stage.
Figure 48 shows an AD711 used as an active attenuator in the
output amplifier’s feedback loop. The active attenuation presents
very low impedance to the feedback resistors, therefore
minimizing the common-mode rejection ratio degradation.
(–INPUT)
PROTECTION
16
2
PROTECTION
15
+VS
3
INPUT
OFFSET
NULL
14
4.44kΩ
4
10kΩ
20kΩ
20kΩ
5
20kΩ
+
–VS
7
+VS
8
–
AD711
–VS
1
15
2
+
13
14
11
12
10
5
6
6
1/2
DAC A
DATA
INPUTS
14
DB0
7
DB7
CS
15
WR
16
2
256:1
AD7528
1
19
6
DAC B
20
1/2
5
AD712
Another method for developing the switching scheme is to
use a DAC. The AD7528 dual DAC, which acts essentially as
a pair of switched resistive attenuators having high analog
linearity and symmetrical bipolar transmission, is ideal in this
application. The multiplying DAC’s advantage is that it can
handle inputs of either polarity or zero without affecting the
programmed gain. The circuit shown uses an AD7528 to set
the gain (DAC A) and to perform a fine adjustment (DAC B).
VOUT
39.2kΩ
1kΩ
28.7kΩ
1kΩ
316kΩ
1kΩ
AUTOZERO CIRCUITS
AD7590
4
VOUT
AD712
3
18
16
–
3
20kΩ
20kΩ
DAC A /DAC B
10
9
20kΩ
10
PROTECTION
4
GND
8
20kΩ
9
RG2 3
17
20kΩ
VSS VDD
20kΩ
Figure 49. Programmable Output Gain Using a DAC
20kΩ
+VS
RG1 16
20kΩ
+VS
OUTPUT
OFFSET
NULL
TO –V
R2
10kΩ
9
10pF
40Ω
G = 1000 11
11
AD524
1µF
35V
Vb
12
40Ω
6
AD524
404Ω
G = 100 12
13
404Ω
20kΩ
20kΩ
4.44kΩ
G = 10 13
–INPUT 2
(+INPUT)
7
VDD A2 A3 A4 WR
Figure 48. Programmable Output Gain
00500-048
+IN
1
PROTECTION
00500-049
(+INPUT)
–IN
+INPUT
(–INPUT) 1
In many applications, it is necessary to provide very accurate
data in high gain configurations. At room temperature, the
offset effects can be nulled by the use of offset trim potentiometers. Over the operating temperature range, however,
offset nulling becomes a problem. The circuit of Figure 50
shows a CMOS DAC operating in bipolar mode and connected
to the reference terminal to provide software controllable offset
adjustments.
Rev. F | Page 20 of 28
AD524
+VS
RG1
16
G = 10
13
G = 100
12
G = 1000
RG2
R3
20kΩ
+VS
15
14
C1
16
AD7524
11
CS
12
WR
13
1
2
OUT1
OUT2
8
1/2
R6
5kΩ
5 +
4
–VS
GND
Figure 50. Software Controllable Offset
In many applications, complex software algorithms for autozero
applications are not available. For those applications, Figure 51
provides a hardware solution.
+VS
15
16
RG1
+
2
16
8
10
13
14
RG2
11
1
9
6
3
–
13
VOUT
AD524
12
7
0.1µF LOW
LEAKAGE
–
–VS
AD711
10
CH
1kΩ
12
+
1
GND
2
200µs
11
AD7510KD
A1
A2
A3
A4
ZERO PULSE
6
11
14-BIT
ADC
0V TO 2V
F.S.
3
1
–
7
In many applications, differential linearity and resolution are of
prime importance in cases where the absolute value of a variable is
less important than changes in value. In these applications, only
the irreducible errors (45 ppm = 0.004%) are significant. Furthermore, if a system has an intelligent processor monitoring the
analog-to-digital output, the addition of an autogain/autozero
cycle removes all reducible errors and may eliminate the requirement for initial calibration. This also reduces errors to 0.004%.
8
VSS
9
To illustrate how instrumentation amplifier specifications are
applied, review a typical case where an AD524 is required to
amplify the output of an unbalanced transducer. Figure 52
shows a differential transducer, unbalanced by 100 Ω, supplying
a 0 mV to 20 mV signal to an AD524C. The output of the IA
feeds a 14-bit ADC with a 0 V to 2 V input voltage range. The
operating temperature range is −25°C to +85°C. Therefore, the
largest change in temperature, ΔT, within the operating range is
from ambient to +85°C (85°C − 25°C = 60°C).
00500-051
VDD
9
10
AD524C
12
ERROR BUDGET ANALYSIS
6 –
7
AD712
5
13
Figure 52. Typical Bridge Application
AD712
1
3 +
10kΩ
4
16
–VS
1/2
R4
10kΩ
+
R5
20kΩ
+VS
2 –
3
350Ω
RG2
–VS
4
RG1
G = 100
7
–
2
9
350Ω
3
350Ω
6
00500-050
MSB
DATA
INPUTS LSB
AD524
VREF
AD589
350Ω
10
1
39kΩ
8
8
11
–INPUT
–VS
+VS
+10V
+
2
00500-052
+INPUT
Figure 51. Autozero Circuit
Rev. F | Page 21 of 28
AD524
Table 5. Error Budget Analysis
Effect on
Absolute
Accuracy
at TA = 25°C
2500 ppm
–
–
2500 ppm
–
Effect on
Absolute
Accuracy
at TA = 85°C
2500 ppm
1500 ppm
–
2500 ppm
1500 ppm
Effect
on
Resolution
–
–
30 ppm
–
–
Error Source
Gain Error
Gain Instability
Gain Nonlinearity
Input Offset Voltage
Input Offset Voltage Drift
AD524C
Specifications
±0.25%
25 ppm
±0.003%
±50 μV, RTI
±0.5 μV/°C
–
Output Offset Voltage 1
Output Offset Voltage Drift1
±2.0 mV
±25 μV/°C
±2.0 mV/20 mV = 1000 ppm
(±25 μV/°C)(60°C)= 1500 μV
1500 μV/20 mV = 750 ppm
1000 ppm
–
1000 ppm
750 ppm
–
–
Bias Current-Source
Imbalance Error
±15 nA
(±15 nA)(100 Ω ) = 1.5 μV
1.5 μV/20 mV = 75 ppm
75 ppm
75 ppm
–
Bias Current-Source
Imbalance Drift
±100 pA/°C
(±100 pA/°C)(100 Ω )(60°C) = 0.6 μV
0.6 μV/20 mV = 30 ppm
–
30 ppm
–
Offset Current-Source
Imbalance Error
±10 nA
(±10 nA)(100 Ω ) = 1 μV
1 μV/20 mV = 50 ppm
50 ppm
50 ppm
–
Offset Current-Source
Imbalance Drift
±100 pA/°C
(100 pA/°C)(100 Ω )(60°C) = 0.6 μV
0.6 μV/20 mV = 30 ppm
–
30 ppm
–
Offset Current-Source
Resistance-Error
±10 nA
(10 nA)(175 Ω ) = 3.5 μV
3.5 μV/20 mV = 87.5 ppm
87.5 ppm
87.5 ppm
–
Offset Current-Source
Resistance-Drift
±100 pA/°C
(100 pA/°C)(175 Ω )(60°C) = 1 μV
1 μV/20 mV = 50 ppm
–
50 ppm
–
Common Mode Rejection 5 V DC
115 dB
115 dB = 1.8 ppm × 5 V = 8.8 μV
8.8 μV/20 mV = 444 ppm
444 ppm
444 ppm
–
Noise, RTI (0.1 Hz to 10 Hz)
0.3 μV p-p
–
6656.5 ppm
–
10516.5 ppm
15 ppm
45 ppm
1
Calculation
±0.25% = 2500 ppm
(25 ppm/°C)(60°C) = 1500 ppm
±0.003% = 30 ppm
±50 μV/20 mV = ±2500 ppm
(±0.5 μV/°C)(60°C) = 30 μV
30 μV/20 mV = 1500 ppm
0.3 μV p-p/20 mV = 15 ppm
Total Error
Output offset voltage and output offset voltage drift are given as RTI figures.
Rev. F | Page 22 of 28
AD524
Other thermocouple types may be accommodated with the
standard resistance values shown in Table 5. For other ranges
of ambient temperature, the equation in Figure 53 may be
solved for the optimum values of RT and RA.
Figure 53 shows a simple application in which the variation
of the cold-junction voltage of a Type J thermocouple-iron ±
constantan is compensated for by a voltage developed in series
by the temperature-sensitive output current of an AD590
semiconductor temperature sensor.
52.3Ω
41.2Ω
61.4Ω
40.2Ω
5.76Ω
+VS
7.5V
IA
TA
2.5V
G = 100
+VS
RA
IRON
VT CONSTANTAN
MEASURING
JUNCTION
AD580
AD590
VA
EO = VT – VA +
~
= VT
52.3Ω
CU
52.3ΩI A + 2.5V
1+
The microprocessor controlled data acquisition system shown
in Figure 54 includes both autozero and autogain capability. By
dedicating two of the differential inputs, one to ground and one
to the A/D reference, the proper program calibration cycles can
eliminate both initial accuracy errors and accuracy errors over
temperature. The autozero cycle, in this application, converts a
number that appears to be ground and then writes that same
number (8-bit) to the AD7524, which eliminates the zero error.
Because its output has an inverted scale, the autogain cycle
converts the A/D reference and compares it with full scale. A
multiplicative correction factor is then computed and applied
to subsequent readings.
52.3Ω
R
+
AD524
EO
–
8.66kΩ
– 2.5V
RT
1kΩ
–VS
OUTPUT
AMPLIFIER
OR METER
NOMINAL VALUE
9135Ω
For a comprehensive study of instrumentation amplifier
design and applications, refer to the Designer’s Guide to
Instrumentation Amplifiers (3rd Edition), available free from
Analog Devices, Inc.
Figure 53. Cold-Junction Compensation
The circuit is calibrated by adjusting RT for proper output
voltage with the measuring junction at a known reference
temperature and the circuit near 25°C. If resistors with low
temperature coefficients are used, compensation accuracy is
to within ±0.5°C, for temperatures between +15°C and +35°C.
2
RG2
+
10
13
AD7507
AD524
12
–
–VREF
20kΩ
20kΩ
–
1/2
AD712
AD574A
AGND
3
1
A0, A2,
EN, A1
VIN
9
6
11
RG1
VREF
AD583
16
–
10kΩ
+
+
AD7524
1/2
5kΩ
AD712
DECODE
LATCH
CONTROL
MICROPROCESSOR
ADDRESS BUS
Figure 54. Microprocessor Controlled Data Acquisition System
Rev. F | Page 23 of 28
00500-054
J
K
E
T
S, R
REFERENCE
JUNCTION
+15°C < TA < +35°C
00500-053
RA
NOMINAL
VALUE
TYPE
AD524
OUTLINE DIMENSIONS
0.005 (0.13) MIN
PIN 1
0.200 (5.08)
MAX
0.080 (2.03) MAX
16
9
1
8
0.840 (21.34) MAX
0.310 (7.87)
0.220 (5.59)
0.060 (1.52)
0.015 (0.38)
0.320 (8.13)
0.290 (7.37)
0.150
(3.81)
MIN
0.200 (5.08)
0.125 (3.18)
0.023 (0.58)
0.014 (0.36)
0.015 (0.38)
0.008 (0.20)
0.100 0.070 (1.78) SEATING
(2.54) 0.030 (0.76) PLANE
BSC
CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.
Figure 55. 16-Lead Side-Brazed Ceramic Dual In-Line [SBDIP]
(D-16)
Dimensions shown in inches and (millimeters)
0.095 (2.41)
0.075 (1.90)
0.358
(9.09)
MAX
SQ
0.358 (9.09)
0.342 (8.69)
SQ
0.200 (5.08)
REF
0.100 (2.54) REF
0.015 (0.38)
MIN
0.075 (1.91)
REF
0.100 (2.54)
0.064 (1.63)
0.011 (0.28)
0.007 (0.18)
R TYP
0.075 (1.91)
REF
0.088 (2.24)
0.054 (1.37)
19
18
3
20
4
0.028 (0.71)
0.022 (0.56)
1
BOTTOM
VIEW
0.055 (1.40)
0.045 (1.14)
0.050 (1.27)
BSC
8
14
13
9
45° TYP
0.150 (3.81)
BSC
022106-A
CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.
Figure 56. 20-Terminal Ceramic Leadless Chip Carrier [LCC]
(E-20)
Dimensions shown in inches and (millimeters)
10.50 (0.4134)
10.10 (0.3976)
9
16
7.60 (0.2992)
7.40 (0.2913)
8
1.27 (0.0500)
BSC
0.30 (0.0118)
0.10 (0.0039)
COPLANARITY
0.10
0.51 (0.0201)
0.31 (0.0122)
10.65 (0.4193)
10.00 (0.3937)
0.75 (0.0295)
0.25 (0.0098)
2.65 (0.1043)
2.35 (0.0925)
SEATING
PLANE
45°
8°
0°
0.33 (0.0130)
0.20 (0.0079)
COMPLIANT TO JEDEC STANDARDS MS-013- AA
CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.
Figure 57. 16-Lead Standard Small Outline Package [SOIC_W]
Wide Body (RW-16)
Dimensions shown in millimeters and (inches)
Rev. F | Page 24 of 28
1.27 (0.0500)
0.40 (0.0157)
032707-B
1
AD524
ORDERING GUIDE
Model
AD524AD
AD524ADZ 1
AD524AE
AD524AR-16
AD524AR-16-REEL
AD524AR-16-REEL7
AD524ARZ-161
AD524ARZ-16-REEL71
AD524BD
AD524BDZ1
AD524BE
AD524CD
AD524CDZ1
AD524SD
AD524SD/883B
5962-8853901EA 2
AD524SE/883B
AD524SCHIPS
1
2
Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−55°C to +125°C
−55°C to +125°C
−55°C to +125°C
−55°C to +125°C
−55°C to +125°C
Package Description
16-Lead SBDIP
16-Lead SBDIP
20-Terminal LCC
16-Lead SOIC_W
16-Lead SOIC_W, 13" Tape and Reel
16-Lead SOIC_W, 7" Tape and Reel
16-Lead SOIC_W
16-Lead SOIC_W, 7”Tape and Reel
16-Lead SBDIP
16-Lead SBDIP
20-Terminal LCC
16-Lead SBDIP
16-Lead SBDIP
16-Lead SBDIP
16-Lead SBDIP
16-Lead SBDIP
20-Terminal LCC
Die
Z = RoHS Compliant Part.
Refer to the official DESC drawing for tested specifications.
Rev. F | Page 25 of 28
Package Option
D-16
D-16
E-20
RW-16
RW-16
RW-16
RW-16
RW-16
D-16
D-16
E-20
D-16
D-16
D-16
D-16
D-16
E-20
AD524
NOTES
Rev. F | Page 26 of 28
AD524
NOTES
Rev. F | Page 27 of 28
AD524
NOTES
©2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D00500-0-11/07(F)
Rev. F | Page 28 of 28