AD746SQ/883B Datasheet AD746JRZ, AD746JNZ, AD746SQ/883B | P7-P9

AD746

–6–

REV. B

POWER SUPPLY BYPASSING

The power supply connections to the AD746 must maintain a

low impedance to ground over a bandwidth of 13 MHz or more.

This is especially important when driving a significant resistive

or capacitive load, since all current delivered to the load comes

from the power supplies. Multiple high quality bypass capacitors

are recommended for each power supply line in any critical

application. A 0.1 µF ceramic and a 1 µF tantalum capacitor as

shown in Figure 20 placed as close as possible to the amplifier

(with short lead lengths to power supply common) will assure

adequate high frequency bypassing, in most applications. A

minimum bypass capacitance of 0.1 µF should be used for any

application.

If only one of the two amplifiers inside the AD746 is to be

utilized, the unused amplifier should be connected as shown in

Figure 21a. Note that the noninverting input should be

grounded and that R

and C

are not required.

Figure 19. THD Test Circuit

Figure 22a. Unity Gain Inverter

Figure 21a. Gain of 2 Follower

Figure 21b. Gain of 2 Follower

Large Signal Pulse Response

Figure 21c. Gain of 2 Follower

Small Signal Pulse Response

Figure 22b. Unity Gain Inverter

Large Signal Pulse Response

Figure 22c. Unity Gain Inverter

Small Signal Pulse Response

Figure 20. Power Supply

Bypassing

AD746

REV. B

–7–

Table I. Performance Summary for the 3 Op Amp

Instrumentation Amplifier Circuit

SETTLE

Gain R

Bandwidth (0.01%)

2 20 kΩ 2.5 MHz 1.0 µs

10 4.04 kΩ 1 MHz 2.0 µs

100 404 Ω 290 kHz 5.0 µs

Figure 25. Settling Time of the 3 Op

Amp Instrumentation Amplifier.

Gain = 10, Horizontal Scale: 0.5

s/Div,

Vertical Scale: 5 V/Div.

Error Signal Scale: 0.01%/Div.

THD Performance Considerations

The AD746 was carefully optimized to offer excellent

performance in terms of total harmonic distortion (THD) in

signal processing applications. The THD level when operating

the AD746 in inverting gain applications will show a gradual

rise from the distortion floor of 20 dB/decade (see Figure 28).

In noninverting applications, care should be taken to balance

the source impedances at both the inverting and noninverting

inputs, to avoid distortion caused by the modulation of input

capacitance inherent in all BiFET op amps.

Figure 26. THD Measurement, Inverter Circuit

Figure 27. THD Measurement, Follower Circuit

A HIGH SPEED 3 OR AMP INSTRUMENTATION

AMPLIFIER CIRCUIT

The instrumentation amplifier circuit shown in Figure 23 can

provide a range of gains from 2 up to 1000 and higher. The

circuit bandwidth is 2.5 MHz at a gain of 2 and 750 kHz at a

gain of 10; settling time for the entire circuit is less than 2 µs to

within 0.01% for a 10 volt step, (G = 10).

Figure 23. A High Performance, 3 Op Amp, Instrumenta-

tion Amplifier Circuit

Figure 24. Pulse Response of the 3

Op Amp Instrumentation Amplifier.

Gain = 10, Horizontal Scale:

0.5

s/Div, Vertical Scale: 5 V/Div.

AD746

–8–

REV. B

C1319–10–9/89

PRINTED IN U.S.A.

Figure 28. THD vs. Frequency Using Standard Distortion

Analyzer

20kΩ

2.21kΩ

2kΩ

SINE WAVE

GENERATOR

20V p-p

OUTPUT

LEVEL

20V p-p

OUT

–

1/2

AD746

–V

1µF 0.1µF

–

1/2

AD746

OUT

1µF 0.1µF

CROSSTALK = 20 LOG

OUT

+ 20dB

Figure 29. Crosstalk Test Circuit

Figure 30. Crosstalk vs. Frequency

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

Mini-DIP (N) Package

Cerdip (Q) Package

Plastic Small Outline

(R) Package

P1-P3 P4-P6 P7-P9

AD746SQ/883B

Mfr. #:

Buy AD746SQ/883B

Manufacturer:

Analog Devices Inc.

Description:

Precision Amplifiers DUAL PREC BIFET 13MHz 18V

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AD746SQ/883B

AD746SQ/883B

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