OP285 Datasheet, PDF(10/16 Page) Analog Devices – Dual 9 MHz Precision Operational Amplifier

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OP285 Datasheet, PDF (10/16 Pages) Analog Devices – Dual 9 MHz Precision Operational Amplifier

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OP285

thereby reducing phase error dramatically. This is shown in

Figure 13 where the 10x composite amplifierâs phase response

exhibits less than 1.5Â° phase shift through 500 kHz. On the other

hand, the single gain stage amplifier exhibits 25Â° of phase shift

over the same frequency range. An additional benefit of the low

phase error configuration is constant group delay, by virtue of

constant phase shift at all frequencies below 500 kHz. Although

this technique is valid for minimum circuit gains of 10, actual

closed-loop magnitude response must be optimized for the

amplifier chosen.

LOW PHASE ERROR

AMPLIFIER RESPONSE

â5

â10

â15

SINGLE STAGE

AMPLIFIER RESPONSE

â20

â25

â30

â35

â40

â45

10k

100k

START 10,000.000Hz

10M

STOP 10,000,000.000Hz

Figure 13. Phase Error Comparison

For a more detailed treatment on the design of low phase error

amplifiers, see Application Note AN-107.

Fast Current Pump

A fast, 30 mA current source, illustrated in Figure 14, takes

advantage of the OP285âs speed and high output current drive.

This is a variation of the Howland current source where a sec-

ond amplifier, A2, is used to increase load current accuracy and

output voltage compliance. With supply voltages of Â± 15 V, the

output voltage compliance of the current pump is Â±8 V. To

keep the output resistance in the Mâ¦ range requires that 0.1%

or better resistors be used in the circuit. The gain of the current

pump can be easily changed according to the equations shown

in the diagram.

VIN1

VIN2

2kâ

3 A1 1

50â

2kâ

A1, A2 = 1/2 OP285

GAIN

R2,

IOUT =

VIN2 â V IN1

â¬VIN

IOUT = (MAX) = Ø30mA

Figure 14. A Fast Current Pump

A Low Noise, High Speed Instrumentation Amplifier

A high speed, low noise instrumentation amplifier, constructed

with a single OP285, is illustrated in Figure 15. The circuit exhibits

less than 1.2 ÂµV p-p noise (RTI) in the 0.1 Hz to 10 Hz band

and an input noise voltage spectral density of 9 nV/âHz (1 kHz)

at a gain of 1000. The gain of the amplifier is easily set by RG

according to the formula:

VOUT = 9.98 kâ¦ + 2

VIN

The advantages of a two op amp instrumentation amplifier

based on a dual op amp is that the errors in the individual am-

plifiers tend to cancel one another. For example, the circuitâs

input offset voltage is determined by the input offset voltage

matching of the OP285, which is typically less than 250 ÂµV.

VIN

AC CMRR TRIM

5pFâ40pF

DC CMRR TRIM

2 A1

4.99â

4.99kâ

A2 7

4.99kâ

VOUT

4.99kâ

500â

A1, A2 = 1/2 OP285

GAIN = 9.98kâ +2

GAIN

100

1000

RG(â)

OPEN

1.24k

102

Figure 15. A High-Speed Instrumentation Amplifier

Common-mode rejection of the circuit is limited by the matching

of resistors R1 to R4. For good common-mode rejection, these

resistors ought to be matched to better than 1%. The circuit was

constructed with 1% resistors and included potentiometer P1

for trimming the CMRR and a capacitor C1 for trimming the

CMRR. With these two trims, the circuitâs common-mode

rejection was better than 95 dB at 60 Hz and better than 65 dB

at 10 kHz. For the best common-mode rejection performance,

use a matched (better than 0.1%) thin-film resistor network for

R1 through R4 and use the variable capacitor to optimize the

circuitâs CMR.

The instrumentation amplifier exhibits very wide small- and

large-signal bandwidths regardless of the gain setting, as shown

in the table. Because of its low noise, wide gain-bandwidth

product, and high slew rate, the OP285 is ideally suited for high

speed signal conditioning applications.

Circuit RG

Circuit Bandwidth

Gain

(â) VOUT = 100 mV p-p VOUT = 20 V p-p

100

1000

Open

1.24 k

102

5 MHz

1 MHz

90 kHz

10 kHz

780 kHz

460 kHz

85 kHz

10 kHz

â10â

REV. A

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