AD737JRZ Analog Devices Inc, AD737JRZ Datasheet - Page 12

AD737JRZ

Manufacturer Part Number

AD737JRZ

Description

IC TRUE RMS/DC CONV LP 8-SOIC

Manufacturer

Analog Devices Inc

Datasheet

1.AD737JNZ.pdf (24 pages)

Specifications of AD737JRZ

Current - Supply

160µA

Voltage - Supply

±2.5 V ~ 16.5 V

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Accuracy %

0.3%

Bandwidth

190kHz

Supply Current

120ÂµA

Power Dissipation Pd

200mW

Supply Voltage Range

2.8V

Digital Ic Case Style

SOIC

No. Of Pins

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

AD737-EVALZ - BOARD EVALUATION FOR AD737

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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Current page: 12 of 24
Download datasheet (482Kb)

AD737

THEORY OF OPERATION

As shown in Figure 24, the AD737 has four functional subsec-

tions: an input amplifier, a full-wave rectifier, an rms core, and a

bias section. The FET input amplifier allows a high impedance,

buffered input at Pin 2 or a low impedance, wide dynamic range

input at Pin 1. The high impedance input, with its low input bias

current, is ideal for use with high impedance input attenuators.

The input signal can be either dc-coupled or ac-coupled to the

input amplifier. Unlike other rms converters, the AD737 permits

both direct and indirect ac coupling of the inputs. AC coupling is

provided by placing a series capacitor between the input signal

and Pin 2 (or Pin 1) for direct coupling and between Pin 1 and

ground (while driving Pin 2) for indirect coupling.

POWER

The output of the input amplifier drives a full-wave precision

rectifier which, in turn, drives the rms core. It is the core that

provides the essential rms operations of squaring, averaging,

and square rooting, using an external averaging capacitor, C

Without C

unprocessed, as is done with the average responding connection

(see Figure 26). In the average responding mode, averaging is

carried out by an RC post filter consisting of an 8 kΩ internal

scale factor resistor connected between Pin 6 and Pin 8 and an

DOWN

–V

OPTIONAL RETURN PATH

CURRENT

MODE

ABSOLUTE

VALUE

NEGATIVE SUPPLY

OP AMP

TRANSLINEAR

POSITIVE SUPP LY

8kΩ

FET

<10pA

SECTION

Figure 24. AD737 True RMS Circuit (Test Circuit)

, the rectified input signal passes through the core

BIAS

CORE

RMS

COMMON

C =

33µF

10µF

0.1µF

8kΩ

–V

COM

OUTPUT

10µF

(OPTIONAL

LPF)

Rev. H | Page 12 of 24

external averaging capacitor, C

tional filtering stage reduces any output ripple that was not

removed by the averaging capacitor.

Finally, the bias subsection permits a power-down function.

This reduces the idle current of the AD737 from 160 μA to

30 μA. This feature is selected by connecting Pin 3 to Pin 7

(+V

TYPES OF AC MEASUREMENT

The AD737 is capable of measuring ac signals by operating as

either an average responding converter or a true rms-to-dc con-

verter. As its name implies, an average responding converter

computes the average absolute value of an ac (or ac and dc)

voltage or current by full-wave rectifying and low-pass filtering

the input signal; this approximates the average. The resulting

output, a dc average level, is then scaled by adding (or reducing)

gain; this scale factor converts the dc average reading to an rms

equivalent value for the waveform being measured. For example,

the average absolute value of a sine wave voltage is 0.636 that of

Therefore, for sine wave voltages, the required scale factor is

1.11 (0.707 divided by 0.636).

In contrast to measuring the average value, true rms measure-

ment is a universal language among waveforms, allowing the

magnitudes of all types of voltage (or current) waveforms to be

compared to one another and to dc. RMS is a direct measure of

the power or heating value of an ac voltage compared to that of

a dc voltage; an ac signal of 1 V rms produces the same amount

of heat in a resistor as a 1 V dc signal.

Mathematically, the rms value of a voltage is defined (using a

simplified equation) as

This involves squaring the signal, taking the average, and then

obtaining the square root. True rms converters are smart recti-

fiers; they provide an accurate rms reading regardless of the

type of waveform being measured. However, average responding

converters can exhibit very high errors when their input signals

deviate from their precalibrated waveform; the magnitude of

the error depends on the type of waveform being measured. As

an example, if an average responding converter is calibrated to

measure the rms value of sine wave voltages and then is used to

measure either symmetrical square waves or dc voltages, the

converter has a computational error 11% (of reading) higher

than the true rms value (see Table 5).

The transfer function for the AD737 is

PEAK

V rms =

; the corresponding rms value is 0.707 times V

OUT

Avg

(

)

. In the rms circuit, this addi-

PEAK

AD737JRZ Analog Devices Inc, AD737JRZ Datasheet - Page 12

AD737JRZ

Specifications of AD737JRZ

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