ltc6910-2 Linear Technology Corporation, ltc6910-2 Datasheet - Page 19

ltc6910-2

Manufacturer Part Number

ltc6910-2

Description

Digitally Controlled Programmable Gain Amplifiers In Sot-23

Manufacturer

Linear Technology Corporation

Datasheet

1.LTC6910-2.pdf (24 pages)

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APPLICATIO S I FOR ATIO

Analog Input and DC Levels

As described in Tables 1, 2 and 3 and under Pin Functions,

the IN pin presents a variable input resistance returned

internally to a potential equal to that at the AGND pin

(within a small offset-voltage error). This input resistance

varies with digital gain setting, becoming infinite (open

circuit) at “zero” gain (digital input 000), and as low as 1k

at high gain settings. It is important to allow for this

input-resistance variation with gain, when driving the

LTC6910-X from other circuitry. Also, as the gain in-

creases above unity, the DC linear input-voltage range

(corresponding to rail-to-rail swing at the OUT pin) shrinks

toward the AGND potential. The output swings positive or

negative around the AGND potential (in the opposite

direction from the input, because the gain is inverting).

AC-Coupled Operation

Adding a capacitor in series with the IN pin makes the

LTC6910-X into an AC-coupled amplifier, suppressing the

source’s DC level (and even minimizing the offset voltage

from the LTC6910-X itself). No further components are

required because the input of the LTC6910-X biases itself

correctly when a series capacitor is added. The IN pin

connects to an internal variable resistor (and floats when

DC open-circuited to a well defined voltage equal to the

AGND input voltage at nonzero gain settings). The value of

this internal input resistor varies with gain setting over a

total range of about 1k to 10k, depending on version (the

rightmost columns of Table 1, Table 2 and Table 3).

Therefore, with a series input capacitor the low frequency

cutoff will also vary with gain. For example, for a low

frequency corner of 1kHz or lower, use a series capacitor

of 0.16 F or larger. A 0.16 F capacitor has a reactance of

1k at 1kHz, giving a 1kHz lower –3dB frequency for gain

settings of 10V/V through 100V/V in the LTC6910-1. If the

LTC6910-1 is operated at lower gain settings with an

0.16 F input capacitor, the higher input resistance will

reduce the lower corner frequency down to 100Hz at a gain

setting of 1V/V. These frequencies scale inversely with the

value of the input capacitor.

Note that operating the LTC6910-X in zero gain mode

(digital inputs 000) open circuits the IN pin and this

demands some care if employed with a series input

capacitor. When the chip enters the zero gain mode, the

opened IN pin tends to freeze the voltage across the

capacitor to the value it held just before the zero gain state.

This can place the IN pin at or near the DC potential of a

supply rail (the IN pin may also drift to a supply potential

in this state due to small junction leakage currents). To

prevent driving the IN pin outside the supply limit and

potentially damaging the chip, avoid AC input signals in

the zero gain state with a series capacitor. Also, switching

later to a nonzero gain value will cause a transient pulse at

the output of the LTC6910-X (with a time constant set by

the capacitor value and the new LTC6910-X input resis-

tance value). This occurs because the IN pin returns to the

AGND potential and transient current flows to charge the

capacitor to a new DC drop.

SNR and Dynamic Range

The term “dynamic range” is much used (and abused)

with signal paths. Signal-to-noise ratio (SNR) is an unam-

biguous comparison of signal and noise levels, measured

in the same way and under the same operating conditions.

In a variable gain amplifier, however, further characteriza-

tion is useful because both noise and maximum signal

level in the amplifier will vary with the gain setting, in

general. In the LTC6910-X, maximum output signal is

independent of gain (and is near the full power supply

voltage, as detailed in the Swing sections of the Electrical

Characteristics table). The maximum input level falls with

increasing gain, and the input-referred noise falls as well

(as listed also in the table). To summarize the useful signal

range in such an amplifier, we define Dynamic Range (DR)

as the ratio of maximum input (at unity gain) to minimum

input-referred noise (at maximum gain). (These two num-

bers are measured commensurately, in RMS Volts.

For deterministic signals such as sinusoids, 1V

2.828V

range of signal levels that will experience an SNR above

unity V/V or 0dB. At a 10V total power supply, DR in the

LTC6910-1 (gains 0V to 100V/V) is typically 120dB (the

ratio of a nominal 9.9V

the 3.4 V

DR for the LTC6910-2 (gains 0V to 64V) is also 120dB; for

P-P

RMS

.) This DR has a physical interpretation as the

LTC6910-2/LTC6910-3

high gain input noise). The corresponding

P-P

, or 3.5V

RMS

LTC6910-1

, maximum input to

RMS

6910123fa

ltc6910-2 Linear Technology Corporation, ltc6910-2 Datasheet - Page 19

ltc6910-2

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