AD629BNZ Analog Devices Inc, AD629BNZ Datasheet - Page 13
AD629BNZ
Manufacturer Part Number
AD629BNZ
Description
IC AMP DIFF 25MA LDRIFT 8DIP
Manufacturer
Analog Devices Inc
Specifications of AD629BNZ
Design Resources
Measuring -48 V High-Side Current Using AD629, AD8603, AD780, and AD7453 (CN0100)
Amplifier Type
Differential
Number Of Circuits
1
Slew Rate
2.1 V/µs
-3db Bandwidth
500kHz
Voltage - Input Offset
100µV
Current - Supply
900µA
Current - Output / Channel
25mA
Voltage - Supply, Single/dual (±)
5 V ~ 36 V, ±2.5 V ~ 18 V
Operating Temperature
-40°C ~ 85°C
Mounting Type
Through Hole
Package / Case
8-DIP (0.300", 7.62mm)
No. Of Amplifiers
1
Input Offset Voltage
500µV
Gain Db Max
1dB
Bandwidth
500kHz
Supply Voltage Range
± 2.5V To ± 18V
Supply Current
900µA
Amplifier Case Style
DIP
Rohs Compliant
Yes
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Output Type
-
Gain Bandwidth Product
-
Current - Input Bias
-
OUTPUT CURRENT AND BUFFERING
The AD629 is designed to drive loads of 2 kΩ to within 2 V of
the rails but can deliver higher output currents at lower output
voltages (see Figure 17). If higher output current is required, the
output of the AD629 should be buffered with a precision op amp,
such as the OP113, as shown in Figure 38. This op amp can swing
to within 1 V of either rail while driving a load as small as 600 Ω.
A GAIN OF 19 DIFFERENTIAL AMPLIFIER
While low level signals can be connected directly to the –IN and
+IN inputs of the AD629, differential input signals can also be
connected, as shown in Figure 39, to give a precise gain of 19.
However, large common-mode voltages are no longer permissible.
Cold junction compensation can be implemented using a
temperature sensor, such as the AD590.
Table 7. AD629 vs. INA117 Error Budget Analysis Example 1 (V
Error Source
ACCURACY, T
TEMPERATURE DRIFT (85°C)
RESOLUTION
Initial Gain Error
Offset Voltage
DC CMR (Over Temperature)
Gain
Offset Voltage
Noise, Typical, 0.01 Hz to 10 Hz, μV p-p
CMR, 60 Hz
Nonlinearity
–V
THERMOCOUPLE
0.1µF
S
–IN
+IN
REF (–)
Figure 39. A Gain of 19 Thermocouple Amplifier
A
1
2
3
4
= 25°C
NC = NO CONNECT
Figure 38. Output Buffering Application
21.1kΩ
380kΩ
380kΩ
V
AD629
REF
380kΩ
20kΩ
REF (–)
–IN
+IN
8
7
6
5
1
2
3
4
NC = NO CONNECT
NC
REF (+)
21.1kΩ
380kΩ
380kΩ
0.1µF
AD629
380kΩ
20kΩ
OP113
+V
–V
S
S
8
7
6
5
0.1µF
0.1µF
AD629
(0.0005 × 10)/10 V × 10
(0.001 V/10 V) × 10
(224 × 10
10 ppm/°C × 60°C
(20 μV/°C × 60°C) × 10
15 μV/10 V × 10
(141 × 10
(10
NC
+V
REF (+)
S
-5
× 10 V)/10 V × 10
+V
0.1µF
S
V
V
-6
-6
OUT
OUT
× 200 V)/10 V × 10
× 1 V)/10 V × 10
Rev. C | Page 13 of 16
6
6
CM
6
6
/10 V
6
= 200 V dc)
6
ERROR BUDGET ANALYSIS EXAMPLE 1
In the dc application that follows, the 10 A output current from
a device with a high common-mode voltage (such as a power
supply or current-mode amplifier) is sensed across a 1 Ω shunt
resistor (see Figure 40). The common-mode voltage is 200 V,
and the resistor terminals are connected through a long pair of
lead wires located in a high noise environment, for example,
50 Hz/60 Hz, 440 V ac power lines. The calculations in Table 7
assume an induced noise level of 1 V at 60 Hz on the leads, in
addition to a full-scale dc differential voltage of 10 V. The error
budget table quantifies the contribution of each error source.
Note that the dominant error source in this example is due to
the dc common-mode voltage.
SHUNT
6
CURRENT
1Ω
OUTPUT
V
Figure 40. Error Budget Analysis Example 1: V
CM
= 200 V DC, R
10 AMPS
200V
TO GROUND
INA117
(0.0005 × 10)/10 V × 10
(0.002 V/10 V) × 10
(500 × 10
Total Accuracy Error
10 ppm/°C × 60°C
(40 μV/°C × 60°C) × 10
Total Drift Error
25 μV/10 V × 10
(500 × 10
(10
Total Resolution Error
Total Error
POWER LINE
-5
CM
60Hz
× 10 V)/10 V × 10
DC
-6
-6
SHUNT
× 200 V)/10 V × 10
× 1 V)/10 V × 10
–V
= 1 Ω, 1 V p-p, 60 Hz Power-Line Interference
6
S
REF (–)
6
0.1µF
–IN
+IN
6
6
/10 V
6
1
2
3
4
NC = NO CONNECT
21.1kΩ
380kΩ
380kΩ
6
6
AD629
380kΩ
20kΩ
IN
AD629
500
100
4480
5080
600
120
720
2
14
10
26
5826
= 10 V Full-Scale,
Error, ppm of FS
8
7
6
5
NC
REF (+)
AD629
INA117
500
200
10,000
10,700
600
240
840
3
50
10
63
11,603
0.1µF
V
OUT
+V
S
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