Ad620 – Analog Devices AD620 User Manual

AD620

REV. E

–11–

Make vs. Buy: A Typical Bridge Application Error Budget
The AD620 offers improved performance over “homebrew”
three op amp IA designs, along with smaller size, fewer compo-
nents and 10

× lower supply current. In the typical application,

shown in Figure 34, a gain of 100 is required to amplify a bridge
output of 20 mV full scale over the industrial temperature range
of –40

°

C to +85

°

C. The error budget table below shows how to

calculate the effect various error sources have on circuit accuracy.

Regardless of the system in which it is being used, the AD620
provides greater accuracy, and at low power and price. In simple

R = 350

⍀

+10V

PRECISION BRIDGE TRANSDUCER

AD620A MONOLITHIC
INSTRUMENTATION
AMPLIFIER, G = 100

“HOMEBREW” IN-AMP, G = 100
*0.02% RESISTOR MATCH, 3PPM/

؇

C TRACKING

**DISCRETE 1% RESISTOR, 100PPM/

؇

C TRACKING

SUPPLY CURRENT = 15mA MAX

100

⍀

**

10k

⍀

*

10k

⍀

**

10k

⍀

*

10k

⍀

*

10k

⍀

**

10k

⍀

*

SUPPLY CURRENT = 1.3mA MAX

OP07D

OP07D

OP07D

AD620A

R

G

499

⍀

REFERENCE

R = 350

⍀

R = 350

⍀

R = 350

⍀

Figure 34. Make vs. Buy

Table I. Make vs. Buy Error Budget

AD620 Circuit

“Homebrew” Circuit

Error, ppm of Full Scale

Error Source

Calculation

Calculation

AD620

Homebrew

ABSOLUTE ACCURACY at T

A

= +25

°

C

Input Offset Voltage,

µ

V

125

µ

V/20 mV

(150

µ

V

×

√

2)/20 mV

1

6,250

10,607

Output Offset Voltage,

µ

V

1000

µ

V/100/20 mV

((150

µ

V

× 2)/100)/20 mV

14,

500

10,

150

Input Offset Current, nA

2 nA

× 350

Ω

/20 mV

(6 nA

× 350

Ω

)/20 mV

14,1

18

14,1

53

CMR, dB

110 dB

→3.16 ppm, × 5 V/20 mV (0.02% Match × 5 V)/20 mV/100

14,

791

10,

500

Total Absolute Error

1

7,558

11,310

DRIFT TO +85

°

C

Gain Drift, ppm/

°

C

(50 ppm + 10 ppm)

× 60

°

C

100 ppm/

°

C Track

× 60

°

C

1

3,600

1

6,000

Input Offset Voltage Drift,

µ

V/

°

C

1

µ

V/

°

C

× 60

°

C/20 mV

(2.5

µ

V/

°

C

Ч

√

2

Ч 60

°

C)/20 mV

1

3,000

10,607

Output Offset Voltage Drift,

µ

V/

°

C

15

µ

V/

°

C

× 60

°

C/100/20 mV

(2.5

µ

V/

°

C

Ч 2 Ч 60

°

C)/100/20 mV

14,

450

10,

150

Total Drift Error

1

7,050

16,757

RESOLUTION

Gain Nonlinearity, ppm of Full Scale

40 ppm

40 ppm

14,1

40

10,1

40

Typ 0.1 Hz–10 Hz Voltage Noise,

µ

V p-p 0.28

µ

V p-p/20 mV

(0.38

µ

V p-p

×

√

2)/20 mV

141,

14

13,1

27

Total Resolution Error

14,1

54

101,

67

Grand Total Error

14,662

28,134

G = 100, V

S

=

±

15 V.

(All errors are min/max and referred to input.)

systems, absolute accuracy and drift errors are by far the most
significant contributors to error. In more complex systems with
an intelligent processor, an autogain/autozero cycle will remove all
absolute accuracy and drift errors leaving only the resolution
errors of gain nonlinearity and noise, thus allowing full 14-bit
accuracy.

Note that for the homebrew circuit, the OP07 specifications for
input voltage offset and noise have been multiplied by

√

2. This

is because a three op amp type in-amp has two op amps at its
inputs, both contributing to the overall input error.