OPA2694ID Datasheet, PDF(14/28 Page) Texas Instruments – Dual, Wideband, Low-Power, Current Feedback Operational Amplifier

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OPA2694ID Datasheet, PDF (14/28 Pages) Texas Instruments – Dual, Wideband, Low-Power, Current Feedback Operational Amplifier

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OPA2694

SBOS320D â SEPTEMBER 2004 â REVISED APRIL 2013

common-mode signals very well, while a line driver

application through a transformer also attenuates the

common-mode signal through to the line.

Figure 7 shows a differential I/O stage configured as an

inverting amplifier. In this case, the gain resistors (RG)

become part of the input resistance for the source. This

provides a better noise performance than the noninverting

configuration, but does limit the flexibility in setting the

input impedance separately from the gain.

VCM

+VCC

1/2

OPA2694

1/2

OPA2694

VCM

â VCC

Figure 7. Inverting Differential I/O Amplifier

The two noninverting inputs provide an easy

common-mode control input. This is particularly easy if the

source is AC-coupled through either blocking caps or a

transformer. In either case, the common-mode input

voltages on the two noninverting inputs again have a gain

of 1 to the output pins, giving particularly easy

common-mode control for single-supply operation. Once

RF is fixed, the input resistors can be adjusted to the

desired gain, but will also be changing the input

impedance as well. The high-frequency, common-mode

gain for this circuit from input to output is the same as for

the signal gain. Again, if the source includes an undesired

common-mode signal, it can be rejected at the input using

blocking caps (for low-frequency and DC common-mode)

or a transformer coupling.

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DC-COUPLED SINGLE-TO-DIFFERENTIAL

CONVERSION

The previous differential output circuits were set up to

receive a differential input as well. A simple way to provide

a DC-coupled single-to-differential conversion using a

dual op amp is shown in Figure 8. Here, the output of the

first stage is simply inverted by the second to provide an

inverting version of a single amplifier design. This

approach works well for lower frequencies, but will start to

depart from ideal differential outputs as the propagation

delay and distortion of the inverting stage adds

significantly to that present at the noninverting output pin.

1VPP

+5V

50Î©

1/2

OPA2694

402Î©

80.6Î©

402Î©

12VPP Differential

1/2

OPA2694

â5V

Figure 8. Single-to-Differential Conversion

The circuit of Figure 8 is set up for a single-ended gain of

6 to the output of the first amplifier, then an inverting gain

of â1 through the second stage to provide a total

differential gain of 12.

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