ltc6910-2 Linear Technology Corporation, ltc6910-2 Datasheet - Page 17

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

Functional Description

The LTC6910 family are small outline, wideband inverting

DC amplifiers whose voltage gain is digitally program-

mable. Each delivers a choice of eight voltage gains,

controlled by the 3-bit digital inputs to the G pins, which

accept CMOS logic levels. The gain code is always mono-

tonic; an increase in the 3-bit binary number (G2 G1 G0)

causes an increase in the gain. Table 1, Table 2 and Table 3

list the nominal voltage gains for LTC6910-1, LTC6910-2

and LTC6910-3 respectively. Gain control within each

amplifier occurs by switching resistors from a matched

array in or out of a closed-loop op amp circuit using MOS

analog switches (Figure 4). Bandwidth depends on gain

setting. Curves in the Typical Performance Characteristics

section show measured frequency responses.

Digital Control

Logic levels for the LTC6910-X digital gain control inputs

(Pins 5, 6, 7) are nominally rail-to-rail CMOS. Logic 1 is V

logic 0 is V

The part is tested with the values listed in the Electrical

Characteristics table (Digital Input “High” and “Low” Volt-

ages), which are 10% and 90% of full excursion on the

inputs. That is, the tested logic levels are 0.27V and 2.43V

with a 2.7V supply, 0.5V and 4.5V levels with 0V and 5V

supply rails, and 0.5V and 4.5V logic levels at 5V sup-

plies. Do not attempt to drive the digital inputs with TTL

logic levels (such as HCT or LS logic), which normally do

not swing near +5V. TTL sources should be adapted with

CMOS drivers or suitable pull-up resistors to 5V so that

they will swing to the positive rail.

Timing Constraints

Settling time in the CMOS gain-control logic is typically

several nanoseconds and faster than the analog signal

path. When amplifier gain changes, the limiting timing is

analog, not digital, because the effects of digital input

changes are observed only through the analog output

(Figure 4). The LTC6910-X’s logic is static (not latched)

and therefore lacks bus timing requirements. However, as

with any programmable-gain amplifier, each gain change

causes an output transient as the amplifier’s output moves,

–

or alternatively 0V when using 5V supplies.

with finite speed, toward a differently scaled version of the

input signal. Varying the gain faster than the output can

settle produces a garbled output signal. The LTC6910-X

analog path settles with a characteristic time constant or

time scale, , that is roughly the standard value for a first

order band limited response:

where f

example, when the upper –3dB frequency is 1MHz, is

about 160ns. The bandwidth, and therefore , varies with

gain (see Frequency Response and –3dB Bandwidth curves

in Typical Performance Characteristics). After a gain change

it is the new gain value that determines the settling time

constant. Exact settling timing depends on the gain change,

the input signal and the possibility of slew limiting at the

output. However as a basic guideline, the range of is 20ns

to 1400ns for the LTC6910-1, 20ns to 900ns for the

LTC6910-2 and 20ns to 120ns for the LTC6910-3. These

numbers correspond to the ranges of –3dB Bandwidth in

the plots of that title under Typical Performance Character-

istics.

Offset Voltage vs Gain Setting

The electrical tables list DC offset (error) voltage at the

inputs of the internal op-amp in Figure 4, V

is the source of DC offsets in the LTC6910-X. The tables

also show the resulting, gain dependent offset voltage

referred to the IN pin, V

related through the feedback/input resistor ratio, which

equals the nominal gain-magnitude setting, G:

Offset voltages at any gain setting can be inferred from this

relationship. For example, an internal offset V

1mV will appear referred to the IN pin as 2mV at a gain

setting G of 1, or 1.5mV at a gain setting of 2. At high gains,

either polarity; it is a statistical parameter centered on

zero.) The MOS input circuitry of the internal op amp in

Figure 4 draws negligible input currents (unlike some op

amps), so only V

offset.

OS(IN)

= 1 / (2 f

-3dB

approaches V

= (1 + 1/G) V

LTC6910-2/LTC6910-3

is the –3dB bandwidth of the amplifier. For

-3dB

OS(OA)

and G affect the overall amplifier’s

OS(IN)

OS(OA)

. (Offset voltage can be of

. These two measures are

LTC6910-1

OS(OA)

, which

6910123fa

ltc6910-2 Linear Technology Corporation, ltc6910-2 Datasheet - Page 17

ltc6910-2

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