LTC2411-1CMS#TR Linear Technology, LTC2411-1CMS#TR Datasheet - Page 35

LTC2411-1CMS#TR

Manufacturer Part Number

LTC2411-1CMS#TR

Description

IC A/DCONV DIFF INPUT&REF 10MSOP

Manufacturer

Linear Technology

Datasheet

1.LTC2411CMSPBF.pdf (40 pages)

Specifications of LTC2411-1CMS#TR

Number Of Bits

Sampling Rate (per Second)

6.8

Data Interface

MICROWIRE™, Serial, SPI™

Number Of Converters

Power Dissipation (max)

1mW

Voltage Supply Source

Single Supply

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

10-TFSOP, 10-MSOP (0.118", 3.00mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

LTC2411-1CMSTR
LTC24111CMSTR

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APPLICATIO S I FOR ATIO

Note that this 4-amplifier topology has advantages over

the typical integrated 3-amplifier instrumentation ampli-

fier in that it does not have the high noise level common in

the output stage that usually dominates when an instru-

mentation amplifier is used at low gain. If this amplifier is

used at a gain of 10, the gain error is only 10ppm and input

referred noise is reduced to 0.15 V

can also be configured to provide gain of up to 50 with high

gain stability and linearity.

Figure 42 shows an example of a single amplifier used to

produce single-ended gain. This topology is best used in

applications where the gain setting resistor can be made

to match the temperature coefficient of the strain gauges.

If the bridge is composed of precision resistors, with only

one or two variable elements, the reference arm of the

bridge can be made to act in conjunction with the feedback

resistor to determine the gain. If the feedback resistor is

incorporated into the design of the load cell, using resis-

tors which match the temperature coefficient of the load-

cell elements, good results can be achieved without the

need for resistors with a high degree of absolute accuracy.

The common mode voltage in this case, is again a function

of the bridge output. Differential gain as used with a 350

bridge is:

9 95

1 175

BRIDGE

350

1 F

Figure 42. Bridge Amplification Using a Single Amplifier

= 9.95 =

RMS

. The buffer stages

4.99k

R1 + 175

R1 + R2

–

LTC1050S8

46.4k

0.1 V

Common mode gain is half the differential gain. The

maximum differential signal that can be used is 1/4 V

as opposed to 1/2 V

Remote Half Bridge Interface

As opposed to full bridge applications, typical half bridge

applications must contend with nonlinearity in the bridge

output, as signal swing is often much greater. Applications

include RTD’s, thermistors and other resistive elements

that undergo significant changes over their span. For

single variable element bridges, the nonlinearity of the half

175

1 F

Figure 43. Remote Half Bridge Interface

20k

PLATINUM

10 F

LTC2411/LTC2411-1

100

25.5k

0.1%

RTD

REF

LTC2411-1

–

LTC2411/

in the 2-amplifier topology above.

–

GND

2411 F42

0.1 F

REF

2.7V TO 5.5V

–

LTC2411-1

LTC2411/

GND

2411 F43

REF

LTC2411-1CMS#TR Linear Technology, LTC2411-1CMS#TR Datasheet - Page 35

LTC2411-1CMS#TR

Specifications of LTC2411-1CMS#TR

Available stocks

Related parts for LTC2411-1CMS#TR