LT1167CS8#TR Linear Technology, LT1167CS8#TR Datasheet - Page 15

LT1167CS8#TR

Manufacturer Part Number

LT1167CS8#TR

Description

IC AMP INSTR PROG PREC LP 8SOIC

Manufacturer

Linear Technology

Datasheet

1.LT1167CS8PBF.pdf (22 pages)

Specifications of LT1167CS8#TR

Amplifier Type

Instrumentation

Number Of Circuits

Slew Rate

1.2 V/µs

Gain Bandwidth Product

1MHz

Current - Input Bias

80pA

Voltage - Input Offset

20µV

Current - Supply

900µA

Current - Output / Channel

27mA

Voltage - Supply, Single/dual (±)

4.6 V ~ 36 V, ±2.3 V ~ 18 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Output Type

-3db Bandwidth

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applicaTions inForMaTion

The amplitude and frequency of the interference can have

an adverse effect on an instrumentation amplifier’s input

stage by causing an unwanted DC shift in the amplifier’s

input offset voltage. This well known effect is called RFI

rectification and is produced when out-of-band interference

is coupled (inductively, capacitively or via radiation) and

rectified by the instrumentation amplifier’s input transis-

tors. These transistors act as high frequency signal detec-

tors, in the same way diodes were used as RF envelope

detectors in early radio designs. Regardless of the type

of interference or the method by which it is coupled into

the circuit, an out-of-band error signal appears in series

with the instrumentation amplifier’s inputs.

To significantly reduce the effect of these out-of-band

signals on the input offset voltage of instrumentation am-

plifiers, simple lowpass filters can be used at the inputs.

These filters should be located very close to the input pins

of the circuit. An effective filter configuration is illustrated

in Figure 5, where three capacitors have been added to the

inputs of the LT1167. Capacitors C

lowpass filters with the external series resistors R

to any out-of-band signal appearing on each of the input

traces. Capacitor C

signal that would appear across the input traces. An added

benefit to using C

rejection is not degraded due to common mode capacitive

Figure 5. Adding a Simple RC Filter at the Inputs to an

Instrumentation Amplifier Is Effective in Reducing Rectification

of High Frequency Out-of-Band Signals

–

1.6k

EXTERNAL RFI

0.001µF

0.1µF

XCM2

XCM1

FILTER

is that the circuit’s AC common mode

forms a filter to reduce any unwanted

–

– 3dB

XCM1

LT1167

–

≈ 500Hz

and C

XCM2

form

1167 F05

S1, 2

OUT

imbalance. The differential mode and common mode time

constants associated with the capacitors are:

Setting the time constants requires a knowledge of the

frequency, or frequencies of the interference. Once this

frequency is known, the common mode time constants can

be set followed by the differential mode time constant. To

avoid any possibility of inadvertently affecting the signal

to be processed, set the common mode time constant an

order of magnitude (or more) larger than the differential

mode time constant. Set the common mode time constants

such that they do not degrade the LT1167’s inherent AC

CMR. Then the differential mode time constant can be set

for the bandwidth required for the application. Setting the

differential mode time constant close to the sensor’s BW

also minimizes any noise pickup along the leads. To avoid

any possibility of common mode to differential mode signal

conversion, match the common mode time constants to

1% or better. If the sensor is an RTD or a resistive strain

gauge, then the series resistors R

sensor is in proximity to the instrumentation amplifier.

“Roll Your Own”—Discrete vs Monolithic LT1167

Error Budget Analysis

The LT1167 offers performance superior to that of “roll

your own” three op amp discrete designs. A typical ap-

plication that amplifies and buffers a bridge transducer’s

differential output is shown in Figure 6. The amplifier, with

its gain set to 100, amplifies a differential, full-scale output

voltage of 20mV over the industrial temperature range. To

make the comparison challenging, the low cost version of

the LT1167 will be compared to a discrete instrumentation

amp made with the A grade of one of the best precision

quad op amps, the LT1114A. The LT1167C outperforms

the discrete amplifier that has lower V

comparable V

Table 1 shows how various errors are calculated and how

each error affects the total error budget. The table shows

the greatest differences between the discrete solution and

DM(LPF)

CM(LPF)

= (2)(R

= (R

S1, 2

drift. The error budget comparison in

)(C

XCM1, 2

)

S1, 2

can be omitted, if the

, lower I

LT1167

1167fb

and

LT1167CS8#TR Linear Technology, LT1167CS8#TR Datasheet - Page 15

LT1167CS8#TR

Specifications of LT1167CS8#TR

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