LTC1992_15 Datasheet, PDF(35/42 Page) Linear Technology – Low Power, Fully Differential Input/Output Amplifier/Driver Family

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LTC1992_15 Datasheet, PDF (35/42 Pages) Linear Technology – Low Power, Fully Differential Input/Output Amplifier/Driver Family

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LTC1992 Family

APPLICATIONS INFORMATION

Table 1. Input Signal Limitations for Some Common Applications

Single Supply Ground Referenced Single-Ended Input Signal, VOCM at Mid-Supply. (The VINSIG Min and Max values listed account for

both the input common mode limits and the output clipping)

+VS

âVS

GAIN VOCM

(V)

(V) (V/V) (V)

2.7

1.35

2.7

1.35

2.7

1.35

2.7

1.35

2.5

VINREF

(V)

VINSIG(MAX)

(V)

2.700

1.350

0.540

0.270

5.000

2.500

1.000

0.500

VINSIG(MIN)

(V)

â2.700

â1.350

â0.540

â0.270

â5.000

â2.500

â1.000

â0.500

VINSIGP-P(MAX)

(VP-P AROUND VINREF)

5.40

2.70

1.08

0.54

10.00

5.00

2.00

1.00

VOUTDIFF(MAX)

(VP-PDIFF)

5.40

10.00

Single Supply Ground Referenced Single-Ended Input Signal, VOCM at Typical ADC Reference Levels. (The VINSIG Min and Max values

listed account for both the input common mode limits and the output clipping)

+VS

âVS

GAIN VOCM

(V)

(V) (V/V) (V)

2.7

VINREF

(V)

VINSIG(MAX)

(V)

2.000

1.000

0.400

0.200

4.000

2.000

0.800

0.400

VINSIG(MIN)

(V)

â2.000

â1.000

â0.400

â0.200

â4.000

â2.000

â0.800

â0.400

VINSIGP-P(MAX)

(VP-P AROUND VINREF)

4.00

2.00

0.80

0.40

8.00

4.00

1.60

0.80

VOUTDIFF(MAX)

(VP-PDIFF)

4.00

8.00

Fully Differential Amplifier Applications

Circuit Analysis

All of the previous applications circuit discussions have as-

sumed perfectly matched symmetrical feedback networks.

To consider the effects of mismatched or asymmetrical

feedback networks, the equations get a bit messier.

Figure 6 lists the basic gain equation for the differential

output voltage in terms of +VIN, âVIN, VOSDIFF, VOUTCM

and the feedback factors Î²1 and Î²2. The feedback factors

are simply the portion of the output that is fed back to the

input summing junction by the RFB-RIN resistive voltage

divider. Î²1 and Î²2 have the range of zero to one. The

VOUTCM term also includes its offset voltage, VOSCM, and

its gain mismatch term, KCM. The KCM term is determined

by the matching of the on-chip RCMP and RCMM resistors

in the common mode level servo (see Figure 2).

While mathematically correct, the basic signal equation

does not immediately yield any intuitive feel for fully

differential amplifier application operation. However, by

nulling out specific terms, some basic observations and

sensitivities come forth. Setting Î²1 equal to Î²2, VOSDIFF

to zero and VOUTCM to VOCM gives the old gain equation

from Figure 3. The ground referenced, single-ended input

signal equation yields the interesting result that the driven

side feedback factor (Î²1) has a very different sensitivity

than the grounded side (Î²2). The CMRR is twice the

feedback factor difference divided by the feedback fac-

tor sum. The differential output offset voltage has two

terms. The first term is determined by the input offset

term, VOSDIFF, and the applicationâs gain. Note that this

term equates to the formula in Figure 3 when Î²1 equals

Î²2. The amount of signal level shifting and the feedback

factor mismatch determines the second term. This term

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