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AD534T
(Rev.:RevC)

Internally Trimmed Precision IC Multiplier

Analog Devices 

AD534

(X1 – X2)(Y1 – Y2), so that the circuit can exhibit a maximum

gain of 10. This connection results in a reduction of bandwidth

to about 80 kHz without the peaking capacitor CF = 200 pF. In

addition, the output offset voltage is increased by a factor of 10

making external adjustments necessary in some applications.

Adjustment is made by connecting a 4.7 MΩ resistor between

Z1 and the slider of a potentiometer connected across the

supplies to provide ±300 mV of trim range at the output.

X INPUT

±10V FS

±12V PK

Y INPUT

±10V FS

±12V PK

X1

+VS

X2

OUT

AD534

SF

Z1

Y1

Z2

Y2

–VS

+15V

90kΩ

10kΩ

OUTPUT, ±12V PK =

(X1 – X2) (Y1 – Y2)

(SCALE = 1V)

OPTIONAL PEAKING

CAPACITOR CF = 200pF

–15V

Figure 16. Connections for Scale Factor of Unity

Feedback attenuation also retains the capability for adding a

signal to the output. Signals can be applied to the high impedance

Z2 terminal where they are amplified by +10 or to the common

ground connection where they are amplified by +1. Input signals

can also be applied to the lower end of the 10 kΩ resistor, giving

a gain of −9. Other values of feedback ratio, up to ×100, can be

used to combine multiplication with gain.

Occasionally, it may be desirable to convert the output to a

current into a load of unspecified impedance or dc level. For

example, the function of multiplication is sometimes followed

by integration; if the output is in the form of a current, a simple

capacitor provides the integration function. Figure 17 shows

how this can be achieved. This method can also be applied in

squaring, dividing, and square rooting modes by appropriate

choice of terminals. This technique is used in the voltage

controlled low-pass filter and the differential input voltage-to-

frequency converter shown in the Applications Information

section.

X INPUT

±10V FS

±12V PK

Y INPUT

±10V FS

±12V PK

X1

+VS

X2

OUT

AD534

SF

Z1

Y1

Z2

Y2

–VS

CURRENT-SENSING

RESISTOR, RS, 2kΩ MIN

IOUT =

(X1 – X2) (Y1 – Y2)

10V

×

1

RS

INTEGRATOR

CAPACITOR

(SEE TEXT)

Figure 17. Conversion of Output to Current

OPERATION AS A SQUARER

Operation as a squarer is achieved in the same fashion as the

multiplier except that the X and Y inputs are used in parallel.

The differential inputs can be used to determine the output

polarity (positive for X1 = Yl and X2 = Y2, negative if either one

of the inputs is reversed). Accuracy in the squaring mode is

typically a factor of 2 better than in the multiplying mode and

the largest errors occurring with small values of output for

input below 1 V.

If the application depends on accurate operation for inputs that

are always less than ±3 V, the use of a reduced value of SF is recom-

mended as described in the Functional Description section.

Alternatively, a feedback attenuator can be used to raise the

output level. This is put to use in the difference-of-squares

application to compensate for the factor of 2 loss involved in

generating the sum term (see Figure 20).

The difference of squares function is also used as the basis for a

novel rms-to-dc converter shown in Figure 27. The averaging

filter is a true integrator, and the loop seeks to zero its input. For

this to occur, (VIN)2 − (VOUT)2 = 0 V (for signals whose period is

well below the averaging time constant). Therefore, VOUT is

forced to equal the rms value of VIN. The absolute accuracy of

this technique is very high; at medium frequencies and for

signals near full scale, it is determined almost entirely by the

ratio of the resistors in the inverting amplifier. The multiplier

scaling voltage affects only open-loop gain. The data shown is

typical of performance that can be achieved with an AD534K,

but even using an AD534J, this technique can readily provide

better than 1% accuracy over a wide frequency range, even for

crest factors in excess of 10.

OPERATION AS A DIVIDER

Figure 18 shows the connection required for division. Unlike

earlier products, the AD534 provides differential operation on

both numerator and denominator, allowing the ratio of two

floating variables to be generated. Further flexibility results

from access to a high impedance summing input to Y1. As with

all dividers based on the use of a multiplier in a feedback loop,

the bandwidth is proportional to the denominator magnitude,

as shown in Figure 14.

X INPUT

(DENOMINATOR)

+

X1

+VS

±10V FS

±12V PK – X2

OUT

AD534

SF

Z1

OPTIONAL

SUMMING

INPUT

Y1

Z2

±10V PK

Y2

–VS

+15V

OUTPUT, ±12V PK =

10V (Z2 – Z1)

(X1 – X2)

+ Y1

Z INPUT

(NUMERATOR)

±10V FS

±12V PK

–15V

Figure 18. Basic Divider Connection

Without additional trimming, the accuracy of the AD534K and

AD534L is sufficient to maintain a 1% error over a 10 V to 1 V

denominator range. This range can be extended to 100:1 by

simply reducing the X offset with an externally generated trim

voltage (range required is ±3.5 mV maximum) applied to the

unused X input (see Figure 3). To trim, apply a ramp of +100 mV

to +V at 100 Hz to both X1 and Z1 (if X2 is used for offset adjust-

ment; otherwise, reverse the signal polarity) and adjust the trim

voltage to minimize the variation in the output

Because the output is near 10 V, it should be ac-coupled for

this adjustment. The increase in noise level and reduction in

bandwidth preclude operation much beyond a ratio of 100 to 1.

Rev. C | Page 13 of 20

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