IVC102 Datasheet, PDF(9/15 Page) Burr-Brown (TI) – PRECISION SWITCHED INTEGRATOR TRANSIMPEDANCE AMPLIFIER

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IVC102 Datasheet, PDF (9/15 Pages) Burr-Brown (TI) – PRECISION SWITCHED INTEGRATOR TRANSIMPEDANCE AMPLIFIER

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INPUT BIAS CURRENT ERRORS

Careful circuit board layout and assembly techniques are

required to achieve the very low input bias current capability

of the IVC102. The critical input connections are at ground

potential, so analog ground should be used as a circuit board

guard trace surrounding all critical nodes. These include

pins 2, 3, 4, 5 and 6. See Figure 4.

Input bias current increases with temperatureâsee typical

performance curve Input Bias Current vs Temperature.

HOLD MODE DROOP

Hold-mode droop is a slow change in output voltage prima-

rily due to op amp input bias current. Droop is specified

using the internal CINT = 100pF and is based on a â100fA

typical input bias current. Current flows out of the inverting

input of the internal op amp.

CHOOSING CINT

Internal capacitors C1, C2 and C3 are high quality metal/

oxide types with low leakage and excellent dielectric char-

acteristics. Temperature stability is excellentâsee typical

curve. They can be connected for CINT = 10pF, 30pF, 40pF,

60pF, 70pF, 90pF or 100pF. Connect unused internal ca-

pacitor pins to analog ground. Accuracy is Â±20%, which

directly influences the gain of the transfer function.

A larger value external CINT can be connected between pins

3 and 10 for slower/longer integration. Select a capacitor

type with low leakage and good temperature stability.

TeflonÂ®, polystyrene or polypropylene capacitors generally

provide excellent leakage, temperature drift and voltage

coefficient characteristics. Lower cost types such as NPO

ceramic, mica or glass may be adequate for many applica-

tions. Larger values for CINT require a longer reset timeâsee

typical curves.

Droop Rate = â100fA

CINT

FREQUENCY RESPONSE

Integration of the input signal for a fixed period produces a

With CINT = 100pF, the droop rate is typically only

1nV/Âµsâslow enough that it rarely contributes significant

error at moderate temperatures.

deep null (zero response) at the frequency 1/TINT and its

harmonics. An ac input current at this frequency (or its

harmonics) has zero average value and therefore produces

Since the input bias current increases with temperature, the

droop rate will also increase with temperature. The droop

rate will approximately double for each 10Â°C increase in

junction temperatureâsee typical curves.

Droop rate is inversely proportional to CINT. If an external

integrator capacitor is used, a low leakage capacitor should

be selected to preserve the low droop performance of the

IVC102.

no output. This property can be used to position response

nulls at critical frequencies. For example, a 16.67ms integra-

tion period produces response nulls at 60Hz, 120Hz, 180Hz,

etc., which will reject ac line frequency noise and its har-

monics. Response nulls can be positioned to reduce interfer-

ence from system clocks or other periodic noise.

Response to all frequencies above f = 1/TINT falls at â20dB/

decade. The effective corner frequency of this single-pole

response is approximately 1/2.8TINT.

INPUT CURRENT RANGE

Extremely low input currents can be measured by integrat-

ing for long periods and/or using a small value for CINT.

Input bias current of the internal op amp is the primary

source of error.

For the simple reset-and-integrate measurement technique,

TINT is equal to the to the time that S2 is open. The switched-

input technique, however, effectively integrates the input

signal throughout the full measurement cycle, including the

reset period and both hold periods. Using the timing shown

in Figure 3, the effective integration time is 1/Ts, where Ts

Larger input currents can be measured by increasing the is the repetition rate of the sampling.

value of CINT and/or using a shorter integration time. Input

currents greater than 200ÂµA should not be applied to the pin

2 input, however. The approximately 1.5kâ¦ series resistance

of S1 will create an input voltage at pin 2 that will begin to

forward-bias internal protection clamp diodes. Any current

that flows through these protection diodes will not be accu-

rately integrated. See âInput Impedanceâ section for more

information on input current-induced voltage.

Input current greater than 200ÂµA can, however, be con-

INPUT IMPEDANCE

The input impedance of a perfect transimpedance circuit is

zero ohms. The input voltage ideally would be zero for any

input current. The actual input voltage when directly driving

the integrator input (pin 3) is proportional to the output slew

rate of the integrator. A 1V/Âµs slew rate produces approxi-

mately 100mV at pin 3. The input of the integrator can be

modeled as a resistance:

nected directly to pin 3, using the simple reset-integrate

technique shown in Figure 1. Current applied at this input

can be externally switched to avoid excessive Iâ¢R voltage

RIN = 10â7/ CINT

(2)

with RIN in â¦ and CINT in Farads.

across S2 during reset. Inputs up to 5mA at pin 3 can be

accurately integrated if CINT is made large enough to limit

slew rate to less than 1V/Âµs. A 5mA input current would

Using the internal CINT = C1 + C2 + C3 = 100pF

(3)

require CINT = 5nF to produce a 1V/Âµs slew rate. The input

current appears as load current to the internal op amp,

RIN = 10â7/100pF = 1kâ¦

reducing its ability to drive an external load.

TeflonÂ® E. I. Du Pont de Nemours & Co.

Â®

IVC102

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