Datasheet AD534TH, AD534TD, AD534T, AD534SH, AD534SE Datasheet (Analog Devices)

PIN CONFIGURATIONS

a

AD534

Internally Trimmed

Precision IC Multiplier

FEATURES
Pretrimmed to ⴞ0.25% max 4-Quadrant Error (AD534L)
All Inputs (X, Y and Z) Differential, High Impedance for

[(X

1 – X2

) (Y1 – Y2)/10 V] + Z2 Transfer Function
Scale-Factor Adjustable to Provide up to X100 Gain
Low Noise Design: 90 ␮V rms, 10 Hz–10 kHz
Low Cost, Monolithic Construction
Excellent Long Term Stability

APPLICATIONS
High Quality Analog Signal Processing
Differential Ratio and Percentage Computations
Algebraic and Trigonometric Function Synthesis
Wideband, High-Crest rms-to-dc Conversion
Accurate Voltage Controlled Oscillators and Filters
Available in Chip Form

REV. B

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.

TO-116 (D-14)

Package

TOP VIEW

(Not to Scale)

14

13

12

11

10

9

8

1

2

3

4

5

6

7

NC = NO CONNECT

X1

+V

S

NC

AD534

OUT
Z1
Z2
NC
–V

S

X2

NC

SF

NC

Y1
Y2

TO-100 (H-10A)

Package

–V

S

+V

S

OUT

Z1

Z2

Y2

Y1

SF

X2

X1

AD534

TOP VIEW

(Not To Scale)

LCC (E-20A)

Package

+V

S

3

21

20 19

NC

X1

X2

NC

–V

S

NC

Y2

Y1

NC

91011

12 13

4
5
6
7
8

NC
NC

SF
NC
NC

18
17
16
15
14

OUT
NC
Z1
NC
Z2

AD534

TOP VIEW

(Not To Scale)

NC = NO CONNECT

PRODUCT DESCRIPTION

The AD534 is a monolithic laser trimmed four-quadrant multi­plier divider having accuracy specifications previously found
only in expensive hybrid or modular products. A maximum

multiplication error of ±0.25% is guaranteed for the AD534L

without any external trimming. Excellent supply rejection, low
temperature coefficients and long term stability of the on-chip
thin film resistors and buried Zener reference preserve accuracy
even under adverse conditions of use. It is the first multiplier to
offer fully differential, high impedance operation on all inputs,
including the Z-input, a feature which greatly increases its flex­ibility and ease of use. The scale factor is pretrimmed to the
standard value of 10.00 V; by means of an external resistor, this
can be reduced to values as low as 3 V.

The wide spectrum of applications and the availability of several
grades commend this multiplier as the first choice for all new

designs. The AD534J (±1% max error), AD534K (±0.5% max)
and AD534L (±0.25% max) are specified for operation over the
0°C to +70°C temperature range. The AD534S (±1% max) and
AD534T (±0.5% max) are specified over the extended tempera­ture range, –55°C to +125°C. All grades are available in her-

metically sealed TO-100 metal cans and TO-116 ceramic DIP
packages. AD534J, K, S and T chips are also available.

PROVIDES GAIN WITH LOW NOISE

The AD534 is the first general purpose multiplier capable of
providing gains up to X100, frequently eliminating the need for
separate instrumentation amplifiers to precondition the inputs.
The AD534 can be very effectively employed as a variable gain
differential input amplifier with high common-mode rejection.
The gain option is available in all modes, and will be found to
simplify the implementation of many function-fitting algorithms

such as those used to generate sine and tangent. The utility of
this feature is enhanced by the inherent low noise of the AD534:

90 µV, rms (depending on the gain), a factor of 10 lower than

previous monolithic multipliers. Drift and feedthrough are also
substantially reduced over earlier designs.

UNPRECEDENTED FLEXIBILITY

The precise calibration and differential Z-input provide a degree
of flexibility found in no other currently available multiplier.
Standard MDSSR functions (multiplication, division, squaring,
square-rooting) are easily implemented while the restriction to
particular input/output polarities imposed by earlier designs has
been eliminated. Signals may be summed into the output, with
or without gain and with either a positive or negative sense.
Many new modes based on implicit-function synthesis have
been made possible, usually requiring only external passive
components. The output can be in the form of a current, if
desired, facilitating such operations as integration.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700 World Wide Web Site: http://www.analog.com
Fax: 781/326-8703 © Analog Devices, Inc., 1999

AD534–SPECIFICATIONS

Model AD534J AD534K AD534L

Min Typ Max Min Typ Max Min Typ Max Units

MULTIPLIER PERFORMANCE

Transfer Function

( X

1

– X2)( Y1– Y2)

10 V

+ Z

2

( X

1

– X2)( Y1– Y2)

10 V

+ Z

2

( X

1

– X2)( Y1– Y2)

10 V

+ Z

2

Total Error

1

(–10 V ≤ X, Y ≤ +10 V) ⴞ1.0 ⴞ0.5 ⴞ0.25 %

T

A

= min to max ±1.5 ±1.0 ±0.5 %

Total Error vs. Temperature ±0.022 ±0.015 ±0.008 %/°C
Scale Factor Error

(SF = 10.000 V Nominal)

2

±0.25 ±0.1 ±0.1 %

Temperature-Coefficient of

Scaling Voltage ±0.02 ±0.01 ±0.005 %/°C
Supply Rejection (±15 V ± 1V) ±0.01 ±0.01 ±0.01 %
Nonlinearity, X (X = 20 V p-p, Y = 10 V) ±0.4 ±0.2 ⴞ0.3 ±0.10 ⴞ0.12 %
Nonlinearity, Y (Y = 20 V p-p, X = 10 V) ±0.2 ± 0.1 ⴞ0.1 ±0.005 ⴞ0.1 %
Feedthrough

3

, X (Y Nulled,

X = 20 V p-p 50 Hz) ±0.3 ±0.15 ⴞ0.3 ±0.05 ⴞ0.12 %
Feedthrough

3

, Y (X Nulled,

Y = 20 V p-p 50 Hz) ±0.01 ±0.01 ⴞ0.1 ±0.003 ⴞ0.1 %
Output Offset Voltage ±5 ⴞ30 ±2 ⴞ15 ±2 ⴞ10 mV
Output Offset Voltage Drift 200 100 100 µV/°C

DYNAMICS

Small Signal BW (V

OUT

= 0.1 rms) 1 1 1 MHz

1% Amplitude Error (C

LOAD

= 1000 pF) 50 50 50 kHz

Slew Rate (V

OUT

20 p-p) 20 20 20 V/µs

Settling Time (to 1%, ∆V

OUT

= 20 V) 2 2 2 µs

NOISE

Noise Spectral-Density SF = 10 V 0.8 0.8 0.8 µV/√Hz

SF = 3 V

4

0.4 0.4 0.4 µV/√Hz

Wideband Noise f = 10 Hz to 5 MHz 1 1 1 mV/rms

Wideband Noise f = 10 Hz to 10 kHz 90 90 90 µV/rms

OUTPUT

Output Voltage Swing ⴞ11 ⴞ11 ⴞ 11 V
Output Impedance (f ≤1 kHz) 0.1 0.1 0.1 Ω
Output Short Circuit Current

(R

L

= 0, TA = min to max) 30 30 30 mA

Amplifier Open Loop Gain (f = 50 Hz) 70 70 70 dB

INPUT AMPLIFIERS (X, Y and Z)

5

Signal Voltage Range (Diff. or CM ±10 ±10 ±10 V

Operating Diff.) ±12 ± 12 ± 12 V
Offset Voltage X, Y ±5 ⴞ20 ±2 ⴞ10 ±2 ⴞ10 mV
Offset Voltage Drift X, Y 100 50 50 µV/°C
Offset Voltage Z ±5 ⴞ30 ±2 ⴞ15 ±2

±

10 mV

Offset Voltage Drift Z 200 100 100 µV/°C
CMRR 60 80 70 90 70 90 dB
Bias Current 0.8 2.0 0.8 2.0 0.8 2.0 µA
Offset Current 0.1 0.1 0.05 0.2 µA
Differential Resistance 10 10 10 MΩ

DIVIDER PERFORMANCE

Transfer Function (X

1

> X2)

10 V

( Z

2

− Z

1

)

( X

1

− X

2

)

+Y

1

10 V

( Z

2

− Z

1

)

( X

1

− X

2

)

+Y

1

10 V

( Z

2

− Z

1

)

( X

1

− X

2

)

+Y

1

Total Error

1

(X = 10 V, –10 V ≤ Z ≤+10 V) ±0.75 ±0.35 ±0.2 %
(X = 1 V, –1 V ≤Z ≤+1 V) ±2.0 ± 1.0 ± 0.8 %
(0.1 V ≤ X ≤ 10 V, –10 V ≤ Z ≤ 10 V) ±2.5 ±1.0 ±0.8 %

SQUARE PERFORMANCE

Transfer Function

( X

1

− X

2

)

2

10 V

+ Z

2

( X

1

− X

2

)

2

10 V

+ Z

2

( X

1

− X

2

)

2

10 V

+ Z

2

Total Error (–10 V ≤ X ≤ 10 V) ±0.6 ±0.3 ±0.2 %

SQUARE-ROOTER PERFORMANCE

Transfer Function (Z

1

≤ Z

2

)

10 V ( Z

2

− Z1) + X

2

10 V ( Z

2

− Z1) + X

2

10 V ( Z

2

− Z1) + X

2

Total Error

1

(1 V ≤ Z ≤ 10 V) ±1.0 ± 0.5 ± 0.25 %

POWER SUPPLY SPECIFICATIONS

Supply Voltage

Rated Performance ±15 ± 15 ±15 V

Operating ±8 ⴞ18 ± 8 ⴞ18 ± 8 ⴞ18 V
Supply Current

Quiescent 4 6 4 6 4 6 mA

PACKAGE OPTIONS

TO-100 (H-10A) AD534JH AD534KH AD534LH
TO-116 (D-14) AD534JD AD534KD AD534LD
Chips AD534K Chips

(@ TA = + 25ⴗC, ⴞV

S

= 15 V, R ≥ 2k

⍀

)

N

OTES

1

Figures given are percent of full scale, ±10 V (i.e., 0.01% = 1 mV).

2

May be reduced down to 3 V using external resistor between –VS and SF.

3

Irreducible component due to nonlinearity: excludes effect of offsets.

4

Using external resistor adjusted to give SF = 3 V.

5

See Functional Block Diagram for definition of sections.

Specifications subject to change without notic

e.

Specifications shown in boldface are tested on all production units at final electrical
test. Results from those tests are used to calculate outgoing quality levels. All min and
max specifications are guaranteed, although only those shown in boldface are tested
on all production units.

REV. B–2–

Model AD534S AD534T

Min Typ Max Min Typ Max Units

MULTIPLIER PERFORMANCE

Transfer Function

( X

1

– X2)( Y1– Y2)

10 V

+ Z

2

( X

1

– X2)( Y1– Y2)

10 V

+ Z

2

Total Error

1

(–10 V ≤ X, Y ≤ +10 V) ⴞ1.0 ⴞ0.5 %

T

A

= min to max ⴞ2.0 ±1.0 %

Total Error vs. Temperature ⴞ0.02 ⴞ0.01 %/°C
Scale Factor Error

(SF = 10.000 V Nominal)

2

±0.25 ±0.1 %

Temperature-Coefficient of

Scaling Voltage ±0.02 ⴞ0.005 %/°C
Supply Rejection (±15 V ± 1V) ±0.01 ±0.01 %
Nonlinearity, X (X = 20 V p-p, Y = 10 V) ±0.4 ±0.2 ⴞ0.3 %

Nonlinearity, Y (Y = 20 V p-p, X = 10 V) ±0.2 ±0.1 ⴞ0.1 %
Feedthrough

3

, X (Y Nulled,

X = 20 V p-p 50 Hz) ±0.3 ±0.15 ⴞ0.3 %
Feedthrough

3

, Y (X Nulled,

Y = 20 V p-p 50 Hz) ±0.01 ±0.01 ⴞ0.1 %
Output Offset Voltage ±5

±

30 ±2 ⴞ15 mV

Output Offset Voltage Drift 500 300 µV/°C

DYNAMICS

Small Signal BW (V

OUT

= 0.1 rms) 1 1 MHz

1% Amplitude Error (C

LOAD

= 1000 pF) 50 50 kHz

Slew Rate (V

OUT

20 p-p) 20 20 V/µs

Settling Time (to 1%, ∆V

OUT

= 20 V) 2 2 µs

NOISE

Noise Spectral-Density SF = 10 V 0.8 0.8 µV/√Hz

SF = 3 V

4

0.4 0.4 µV/√Hz

Wideband Noise f = 10 Hz to 5 MHz 1.0 1.0 mV/rms

Wideband Noise f = 10 Hz to 10 kHz 90 90 µV/rms

OUTPUT

Output Voltage Swing

±

11

±

11 V

Output Impedance (f ≤ 1 kHz) 0.1 0.1 Ω
Output Short Circuit Current

(R

L

= 0, TA = min to max) 30 30 mA

Amplifier Open Loop Gain (f = 50 Hz) 70 70 dB

INPUT AMPLIFIERS (X, Y and Z)

5

Signal Voltage Range (Diff. or CM ±10 ±10 V

Operating Diff.) ±12 ±12 V
Offset Voltage X, Y ±5 ⴞ20 ±2 ⴞ10 mV
Offset Voltage Drift X, Y 100 150 µV/°C
Offset Voltage Z ±5 ⴞ30 ±2 ⴞ15 mV
Offset Voltage Drift Z 500 300 µV/°C
CMRR 60 80 70 90 dB
Bias Current 0.8 2.0 0.8 2.0 µA
Offset Current 0.1 0.1 µA
Differential Resistance 10 10 MΩ

DIVIDER PERFORMANCE

Transfer Function (X1 > X2)

10 V

( Z

2

− Z

1

)

( X

1

− X

2

)

+Y

1

10 V

( Z

2

− Z

1

)

( X

1

− X

2

)

+Y

1

Total Error

1

(X = 10 V, –10 V ≤Z ≤+10 V) ±0.75 ±0.35 %
(X = 1 V, –1 V ≤ Z ≤ +1 V) ±2.0 ±1.0 %
(0.1 V ≤ X ≤ 10 V, –10 V ≤Z ≤ 10 V) ±2.5 ±1.0 %

SQUARE PERFORMANCE

Transfer Function

( X

1

− X

2

)

2

10 V

+ Z

2

( X

1

− X

2

)

2

10 V

+ Z

2

Total Error (–10 V ≤ X ≤ 10 V) ±0.6 ±0.3 %

SQUARE-ROOTER PERFORMANCE

Transfer Function (Z

1

≤ Z

2

)

10 V ( Z

2

− Z1) + X

2

10 V ( Z

2

− Z1) + X

2

Total Error

1

(1 V ≤ Z ≤ 10 V) ±1.0 ±0.5 %

POWER SUPPLY SPECIFICATIONS

Supply Voltage

Rated Performance ±15 ±15 V

Operating ±8 ⴞ22 ±8 ⴞ22 V
Supply Current

Quiescent 4 6 4 6 mA

PACKAGE OPTIONS

TO-100 (H-10A) AD534SH AD534TH
TO-116 (D-14) AD534SD AD534TD
E-20A AD534SE
Chips AD534S Chips AD534T Chips

AD534

N

OTES

1

Figures given are percent of full scale, ±10 V (i.e., 0.01% = 1 mV).

2

May be reduced down to 3 V using external resistor between –VS and SF.

3

Irreducible component due to nonlinearity: excludes effect of offsets.

4

Using external resistor adjusted to give SF = 3 V.

5

See Functional Block Diagram for definition of sections.

Specifications subject to change without notice.

REV. B –3–

S

pecifications shown in boldface are tested on all production units at final electrical
test. Results from those tests are used to calculate outgoing quality levels. All min and
max specifications are guaranteed, although only those shown in boldface are tested
on all production units.

AD534

–4– REV. B

ABSOLUTE MAXIMUM RATINGS

AD534J, K, L AD534S, T

Supply Voltage ±18 V ±22 V
Internal Power Dissipation 500 mW *
Output Short-Circuit to Ground Indefinite *
Input Voltages, X1 X2 Y1 Y2 Z1 Z

2

±V

S

*

Rated Operating Temperature Range 0°C to +70°C –55°C to

+125°C
Storage Temperature Range –65°C to +150°C*
Lead Temperature Range, 60 s Soldering +300°C*

*Same as AD534J Specs.

ORDERING GUIDE

Model Temperature Range Package Description Package Option

AD534JD 0°C to +70°C Side Brazed DIP D-14
AD534KD 0°C to +70°C Side Brazed DIP D-14
AD534LD 0°C to +70°C Side Brazed DIP D-14
AD534JH 0°C to +70°C Header H-10A
AD534JH/+ 0°C to +70°C Header H-10A
AD534KH 0°C to +70°C Header H-10A
AD534KH/+ 0°C to +70°C Header H-10A
AD534LH 0°C to +70°C Header H-10A
AD534K Chip 0°C to +70°C Chip
AD534SD –55°C to +125°C Side Brazed DIP D-14
AD534SD/883B –55°C to +125°C Side Brazed DIP D-14
AD534TD –55°C to +125°C Side Brazed DIP D-14
AD534TD/883B –55°C to +125°C Side Brazed DIP D-14
JM38510/13902BCA –55°C to +125°C Side Brazed DIP D-14
JM38510/13901BCA –55°C to +125°C Side Brazed DIP D-14
AD534SE –55°C to +125°C LCC E-20A
AD534SE/883B –55°C to +125°C LCC E-20A
AD534TE/883B –55°C to +125°C LCC E-20A
AD534SH –55°C to +125°C Header H-10A
AD534SH/883B –55°C to +125°C Header H-10A
AD534TH –55°C to +125°C Header H-10A
AD534TH/883B –55°C to +125°C Header H-10A
JM38510/13902BIA –55°C to +125°C Header H-10A
JM38510/13901BIA –55°C to +125°C Header H-10A
AD534S Chip –55°C to +125°C Chip
AD534T Chip –55°C to +125°C Chip

The

rmal C

haracteristics

Thermal Resistance θJC = 25°C/W for H-10A

θ

JA

= 150°C/W for H-10A

θ

JC

= 25°C/W for D-14 or E-20A

θ

JA

= 95°C/W for D-14 or E-20A

X

1

+V

S

OUT

Y

2

–V

S

Z

2

Y

1

SF

X

2

Z

1

THE AD534 IS AVAILABLE IN LASER - TRIMMED CHIP FORM

0.076
(1.93)

0.100 (2.54)

CHIP DIMENSIONS AND BONDING DIAGRAM

Dimensions shown in inches and (mm).

Contact factory for latest dimensions.

470kV

50kV

1kV

TO APPROPRIATE
INPUT TERMINAL

+V

S

–V

S

Figure 1. Optional Trimming Configuration

CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD534 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.

WARNING!

ESD SENSITIVE DEVICE

AD534

REV. B –5–

FUNCTIONAL DESCRIPTION

Figure 2 is a functional block diagram of the AD534. Inputs are
converted to differential currents by three identical voltage-to­current converters, each trimmed for zero offset. The product
of the X and Y currents is generated by a multiplier cell using
Gilbert’s translinear technique. An on-chip “Buried Zener”
provides a highly stable reference, which is laser trimmed to
provide an overall scale factor of 10 V. The difference between
XY/SF and Z is then applied to the high gain output amplifier.
This permits various closed loop configurations and dramati­cally reduces nonlinearities due to the input amplifiers, a domi­nant source of distortion in earlier designs. The effectiveness of
the new scheme can be judged from the fact that under typical
conditions as a multiplier the nonlinearity on the Y input, with

X at full scale (±10 V), is ±0.005% of FS; even at its worst
point, which occurs when X = ±6.4 V, it is typically only
±0.05% of FS Nonlinearity for signals applied to the X input,

on the other hand, is determined almost entirely by the multi­plier element and is parabolic in form. This error is a major
factor in determining the overall accuracy of the unit and hence
is closely related to the device grade.

V-1

X

1

X

2

V-1

Y

1

Y

2

V-1

Z

1

Z

2

SF

AD534

+V

S

–V

S

A

OUT

TRANSFER FUNCTION

V

O

= A – (Z1 – Z2)

(X

1

– X2) (Y1 – Y2)

SF

HIGH GAIN
OUTPUT
AMPLIFIER

+
–

+
–

+
–

STABLE

REFERENCE

AND BIAS

TRANSLINEAR

MULTIPLIER

ELEMENT

0.75 ATTEN

Figure 2. Functional Block Diagram

The generalized transfer function for the AD534 is given by:

V

OUT

= A

( X

1

− X

2

)(Y

1−Y2

)

SF

−(Z1− Z

2

)











where A = open loop gain of output amplifier, typically

70 dB at dc

X, Y, Z = input voltages (full scale = ±SF, peak =

±1.25 SF)

SF = scale factor, pretrimmed to 10.00 V but adjustable
by the user down to 3 V.

In most cases the open loop gain can be regarded as infinite,
and SF will be 10 V. The operation performed by the AD534,
can then be described in terms of equation:

( X

1

− X

2

)(Y

1−Y2

) =10 V ( Z1− Z

2

)

The user may adjust SF for values between 10.00 V and 3 V by
connecting an external resistor in series with a potentiometer
between SF and –V

S

. The approximate value of the total resis-

tance for a given value of SF is given by the relationship:

R

SF

=5.4K

SF

10 −SF

Due to device tolerances, allowance should be made to vary RSF;

by ±25% using the potentiometer. Considerable reduction in

bias currents, noise and drift can be achieved by decreasing SF.
This has the overall effect of increasing signal gain without the
customary increase in noise. Note that the peak input signal is

always limited to 1.25 SF (i.e., ±5 V for SF = 4 V) so the overall

transfer function will show a maximum gain of 1.25. The per­formance with small input signals, however, is improved by
using a lower SF since the dynamic range of the inputs is now
fully utilized. Bandwidth is unaffected by the use of this option.

Supply voltages of ±15 V are generally assumed. However,
satisfactory operation is possible down to ±8 V (see Figure 16).

Since all inputs maintain a constant peak input capability of

±1.25 SF some feedback attenuation will be necessary to
achieve output voltage swings in excess of ±12 V when using

higher supply voltages.

OPERATION AS A MULTIPLIER

Figure 3 shows the basic connection for multiplication. Note
that the circuit will meet all specifications without trimming.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

= + Z

2

(X1 – X2) (Y1 – Y2)

10V

OUTPUT , 612V PK

X INPUT

610V FS

612V PK

Y INPUT

610V FS

612V PK

+15V

OUT

–V

S

+V

S

–15V

OPTIONAL SUMMING
INPUT, Z, 610V PK

SF

Figure 3. Basic Multiplier Connection

In some cases the user may wish to reduce ac feedthrough to a
minimum (as in a suppressed carrier modulator) by applying an

external trim voltage (±30 mV range required) to the X or Y

input (see Figure 1). Figure 19 shows the typical ac feedthrough
with this adjustment mode. Note that the Y input is a factor of
10 lower than the X input and should be used in applications
where null suppression is critical.

The high impedance Z

2

terminal of the AD534 may be used to
sum an additional signal into the output. In this mode the out­put amplifier behaves as a voltage follower with a 1 MHz small

signal bandwidth and a 20 V/µs slew rate. This terminal should

always be referenced to the ground point of the driven system,
particularly if this is remote. Likewise, the differential inputs
should be referenced to their respective ground potentials to
realize the full accuracy of the AD534.

AD534

–6– REV. B

A much lower scaling voltage can be achieved without any re­duction of input signal range using a feedback attenuator as
shown in Figure 4. In this example, the scale is such that V

OUT

= XY, 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 C

F

= 200 pF. In addition,
the output offset voltage is increased by a factor of 10 making
external adjustments necessary in some applications. Adjust-

ment is made by connecting a 4.7 MΩ resistor between Z

1

and

the slider of a pot connected across the supplies to provide

±300 mV of trim range at the output.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

X INPUT

610V FS

612V PK

Y INPUT

610V FS
612V PK

+15V

OUT

–V

S

+V

S

–15V

OPTIONAL
PEAKING
CAPACITOR
C

F

= 200pF

90kV

10kV

SF

OUTPUT , 612V PK
= (X

1

– X2) (Y1 – Y2)

(SCALE = 1V)

Figure 4. Connections for Scale-Factor of Unity

Feedback attenuation also retains the capability for adding a
signal to the output. Signals may be applied to the high imped­ance Z

2

terminal where they are amplified by +10 or to the

common ground connection where they are amplified by +1.

Input signals may also be applied to the lower end of the 10 kΩ

resistor, giving a gain of –9. Other values of feedback ratio, up
to X100, 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 will provide the integration function. Figure 5 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 voltage­controlled low-pass filter and the differential-input voltage-to­frequency converter shown in the Applications section.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

1

RS

(X1 – X2) (Y1 – Y2)

I

OUT

=

10V

INTEGRATOR

CAPACITOR

(SEE TEXT)

X INPUT

610V FS
612V PK

Y INPUT

610V FS
612V PK

OUT

–V

S

+V

S

CURRENT-SENSING
RESISTOR, R

S

, 2kV MIN

SF

Figure 5. 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 X

1

= 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, 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

recommended as described in the Functional Description sec­tion (previous page). Alternatively, a feedback attenuator may
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 8).

The difference-of-squares function is also used as the basis for a
novel rms-to-dc converter shown in Figure 15. The averaging
filter is a true integrator, and the loop seeks to zero its input.
For this to occur, (V

IN

)2 – (V

OUT

)2 = 0 (for signals whose period

is well below the averaging time-constant). Hence V

OUT

is

forced to equal the rms value of V

IN

. 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.

AD534

REV. B –7–

OPERATION AS A DIVIDER

The AD535, a pin-for-pin functional equivalent to the AD534,
has guaranteed performance in the divider and square-rooter
configurations and is recommended for such applications.

Figure 6 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 Y

1

. 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 23.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

10V (Z2 – Z1)

=

(X

1

– X2)

OUTPUT, 612V PK

+ Y

1

Z INPUT
(NUMERATOR)
610V FS, 612V PK

X INPUT

(DENOMINATOR)

+10V FS
+12V PK

OPTIONAL

SUMMING

INPUT

610V PK

OUT

–V

S

+V

S

SF

+

–

+15V

–15V

Figure 6. Basic Divider Connection

Without additional trimming, the accuracy of the AD534K
and L is sufficient to maintain a 1% error over a 10 V to 1 V
denominator range. This range may be extended to 100:1 by
simply reducing the X offset with an externally generated trim

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

X input (see Figure 1). To trim, apply a ramp of +100 mV to
+V at 100 Hz to both X

1

and Z1 (if X2 is used for offset adjust­ment, otherwise reverse the signal polarity) and adjust the trim
voltage to minimize the variation in the output.*

Since the output will be 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.

As with the multiplier connection, overall gain can be intro­duced by inserting a simple attenuator between the output and
Y

2

terminal. This option, and the differential-ratio capability of
the AD534 are utilized in the percentage-computer application
shown in Figure 12. This configuration generates an output
proportional to the percentage deviation of one variable (A) with
respect to a reference variable (B), with a scale of one volt per
percent.

OPERATION AS A SQUARE ROOTER

The operation of the AD534 in the square root mode is shown
in Figure 7. The diode prevents a latching condition which
could occur if the input momentarily changes polarity. As
shown, the output is always positive; it may be changed to a
negative output by reversing the diode direction and interchang­ing the X inputs. Since the signal input is differential, all combi­nations of input and output polarities can be realized, but
operation is restricted to the one quadrant associated with each
combination of inputs.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

OUTPUT, 612V PK

10V (Z2 – Z1) +X

2

=

Z INPUT
10V FS
12V PK

OPTIONAL

SUMMING

INPUT,

X, 610V PK

OUT

–V

S

+V

S

SF

+15V

–15V

REVERSE
THIS AND X
INPUTS FOR
NEGATIVE
OUTPUTS

R

L

(MUST BE
PROVIDED)

+

–

Figure 7. Square-Rooter Connection

In contrast to earlier devices, which were intolerant of capacitive
loads in the square root modes, the AD534 is stable with all
loads up to at least 1000 pF. For critical applications, a small
adjustment to the Z input offset (see Figure 1) will improve
accuracy for inputs below 1 V.

*See the AD535 data sheet for more details.

AD534–Applications Section

–8–

The versatility of the AD534 allows the creative designer to
implement a variety of circuits such as wattmeters, frequency
doublers and automatic gain controls to name but a few.

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

OUTPUT =

A2 – B

2

10V

OUT

–V

S

+V

S

SF

+15V

–15V

A – B

2

A

B

A + B

2

30kV

10kV

Figure 8. Difference-of-Squares

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

OUTPUT, 612V PK

=

EC E

S

0.1V

OUT

–V

S

+V

S

SF

+15V

–15V

SIGNAL INPUT,

E

S

, 65V PK

39kV

1kV

0.005mF

–V

S

CONTROL INPUT,

E

C

, ZERO TO 65V

SET

GAIN

1kV 2kV

NOTES:

1) GAIN IS X 10 PER-VOLT OF E

C

, ZERO TO X 50

2) WIDEBAND (10Hz – 30kHz) OUTPUT NOISE IS 3mV RMS, TYP

CORRESPONDING TO A.F.S. S/N RATIO OF 70dB

3) NOISE REFERRED TO SIGNAL INPUT, WITH E

C

= 65V, IS 60mV RMS, TYP

4) BANDWITH IS DC TO 20kHz, –3dB, INDEPENDENT OF GAIN

Figure 9. Voltage-Controlled Amplifier

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

OUTPUT = (10V) sin u

OUT

–V

S

+V

S

SF

+15V

–15V

4.7kV

4.3kV

18kV

10kV

USING CLOSE TOLERANCE RESISTORS AND AD534L, ACCURACY
OF FIT IS WITHIN 60.5% AT ALL POINTS. u IS IN RADIANS.

INPUT, E

u

0 TO +10V

WHERE u =

p E

u

2 10V

3kV

Figure 10. Sine-Function Generator

X

1

X

2

Y

1

Y

2

Z

1

Z

2

OUTPUT = 16 EC sin vt

10V

E

M

OUT

–V

S

+V

S

SF

+15V

–15V

THE SF PIN OR A Z-ATTENUATOR CAN BE USED TO PROVIDE OVERALL
SIGNAL AMPLIFICATION, OPERATION FROM A SINGLE SUPPLY POSSIBLE;
BIAS Y

2

TO VS/2.

CARRIER

INPUT

E

C

sin vt

MODULATION

INPUT, 6E

M

AD534

Figure 11. Linear AM Modulator

9kV

1kV

X

1

X

2

Y

1

Y

2

Z

2

Z

1

AD534

OUTPUT = (100V)

B

A – B

(1% PER VOLT)

OUT

–V

S

+V

S

SF

+15V

–15V

OTHER SCALES, FROM 10% PER VOLT TO 0.1% PER VOLT
CAN BE OBTAINED BY ALTERING THE FEEDBACK RATIO.

B INPUT

(+VE ONLY)

A INPUT
(6)

Figure 12. Percentage Computer

X

1

X

2

Y

1

Y

2

Z

1

Z

2

OUTPUT, 65V/PK
= (10V)

1 + y

y

(10V)

Y

WHERE y =

OUT

–V

S

+V

S

SF

+15V

–15V

INPUT, Y 610V FS

AD534

Figure 13. Bridge-Linearization Function

AD534

REV. B –9–

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

PINS 5, 6, 8 TO +15V
PINS 1, 4 TO –15V

EC 1
40 CR

f =

OUT

–V

S

+V

S

SF

+15V

–15V

CONTROL

INPUT, E

C

100mV TO 10V

500V 2.2kV

2

3

7

(= R)

ADJ
1kHz

+15V

ADJ 8kHz

82kV

39kV

3-30p

0.01

(= C)

AD211

= 1kHz PER VOLT
WITH VALUES SHOWN

OUTPUT
615V APPROX.

2kV

–

+

CALIBRATION PROCEDURE:
WITH E

C

= 1.0V, ADJUST POT TO SET f = 1.000kHz. WITH EC = 8.0V ADJUST
TRIMMER CAPACITOR TO SET f = 8.000kHz. LINEARITY WILL TYPICALLY BE
WITHIN 6 0.1% OF FS FOR ANY OTHER INPUT.

DUE TO DELAYS IN THE COMPARATOR, THIS TECHNIQUE IS NOT SUITABLE
FOR MAXIMUM FREQUENCIES ABOVE 10kHz. FOR FREQUENCIES ABOVE
10kHz THE AD537 VOLTAGE-TO-FREQUENCY CONVERTER IS RECOMMENDED.

A TRIANGLE-WAVE OF 65V PK APPEARS ACROSS THE 0.01mF CAPACITOR; IF
USED AS AN OUTPUT, A VOLTAGE-FOLLOWER SHOULD BE INTERPOSED.

Figure 14. Differential-Input Voltage-to-Frequency Converter

RMS + DC

AC RMS

X

1

X

2

Y

1

Y

2

Z

1

Z

2

AD534

OUT

–V

S

+V

S

SF

–
+

10kV

–

+

10kV

20kV

+15V

10kV

10kV

10MV

5kV

AD741K

AD741J

10mF SOLID Ta

+

OUTPUT
0 TO +5V

20kV

–15V

ZERO

ADJ

+15V

10mF

NONPOLAR

INPUT

5V RMS FS

610V PEAK

MATCHED TO 0.025%

10kV

MODE

CALIBRATION PROCEDURE:
WITH 'MODE' SWITCH IN 'RMS + DC' POSITION, APPLY AN INPUT OF +1.00VDC.

ADJUST ZERO UNTIL OUTPUT READS SAME AS INPUT. CHECK FOR INPUTS
OF 610V; OUTPUT SHOULD BE WITHIN 60.05% (5mV).

ACCURACY IS MAINTAINED FROM 60Hz TO 100kHz, AND IS TYPICALLY HIGH
BY 0.5% AT 1MHz FOR V

IN

= 4V RMS (SINE, SQUARE OR TRIANGULAR-WAVE).

PROVIDED THAT THE PEAK INPUT IS NOT EXCEEDED, CREST-FACTORS UP
TO AT LEAST TEN HAVE NO APPRECIABLE EFFECT ON ACCURACY .

INPUT IMPEDANCE IS ABOUT 10kV; FOR HIGH (10MV) IMPEDANCE, REMOVE
MODE SWITCH AND INPUT COUPLING COMPONENTS.

FOR GUARANTEED SPECIFICATIONS THE AD536A AND AD636 ARE OFFERED
AS A SINGLE PACKAGE RMS-TO-DC CONVERTER.

Figure 15. Wideband, High-Crest Factor, RMS-to-DC Converter

AD534–Typical Performance Curves

–10–

(typical at +25ⴗC, with VS = ⴞ15 V dc, unless otherwise noted)

100

10

1

FREQUENCY – Hz

0.1

PK-PK FEEDTHROUGH – mV

Y-FEEDTHROUGH

X-FEEDTHROUGH

1000

10 100 1k 10k 100k 1M 10M

Figure 19. AC Feedthrough vs. Frequency

1.5

1

0.5

FREQUENCY – Hz

0

NOISE SPECTRAL DENSITY – mV/ Hz

SCALING VOLTAGE = 10V

SCALING VOLTAGE = 3V

10 100 1k 10k 100k

Figure 20. Noise Spectral Density vs. Frequency

100

90

80

70

60

50

2.5 5 7.5 10
SCALING VOLTAGE, SF – Volts

CONDITIONS:
10Hz – 10kHz BANDWIDTH

OUTPUT NOISE VOLTAGE – mV rms

Figure 21. Wideband Noise vs. Scaling Voltage

14

12

10

8

6

4

8 10 12 14 16 18 20

POSITIVE OR NEGATIVE SUPPLY – Volts

PEAK POSITIVE OR NEGATIVE SIGNAL – Volts

OUTPUT, RL 2kV

ALL INPUTS, SF = 10V

Figure 16. Input/Output Signal Range vs. Supply Voltages

800

700

600

500

400

300

200

100

–60 –40 –20 0 20 40 60 80 100 120 140

TEMPERATURE – 8C

0

BIAS CURRENT – nA

SCALING VOLTAGE = 10V

SCALING VOLTAGE = 3V

Figure 17. Bias Currents vs. Temperature
(X, Y or Z Inputs)

90

80

70

60

50

30

20

10

FREQUENCY – Hz

40

0

CMRR – dB

TYPICAL FOR

ALL INPUTS

100 1k 10k 100k 1M

Figure 18. Common-Mode Rejection Ratio vs. Frequency

AD534

REV. B –11–

0

–10

FREQUENCY – Hz

–20

OUTPUT RESPONSE – dB

0dB = 0.1V RMS, RL= 2kV

–30

WITH X10
FEEDBACK
ATTENUATOR

CL = 0pF

CL 1000pF

C

F

200pF

CL 1000pF
C

F

= 0

10

10k

100k

1M 10M

NORMAL
CONNECTION

Figure 22. Frequency Response as a Multiplier

( )

+20

0

+40

1k 10k 100k 1M 10M

FREQUENCY – Hz

–20

OUTPUT – dB

V

O

V

Z

VX = 10V dc
V

Z

= 1V rms

VX = 1V dc
V

Z

= 100mV rms

VX = 100mV dc
V

Z

= 10mV rms

+60

Figure 23. Frequency Response vs. Divider Denominator
Input Voltage

AD534

–12– REV. B

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

PRINTED IN U.S.A.

C495e–0–6/99

H-10A Package

TO-100

368

0.034 (0.86)

0.028 (0.71)

0.045 (1.14)

0.029 (0.74)

0.115 (2.92)

6

8

5

7

1

4

2

3

9

10

REFERENCE PLANE

SEATING PLANE

0.355 (9.02)

0.305 (7.75)

0.562 (14.30)

0.500 (12.70)

0.370 (9.40)

0.335 (8.51)

0.044 (1.12)

0.032 (0.81)

0.019 (0.48)

0.016 (0.41)

0.021 (0.53)

0.016 (0.41)

0.185 (4.70)

0.165 (4.19)

(DIM. A)

(DIM. B)

0.040 (1.01)

0.010 (0.25)

0.23 (5.84)

D-14 Package

TO-116

PIN 1

0.029 60.010
(7.37 60.25)

0.040 R
(1.02)

8

7

14

1

0.047 60.007

0.100
(2.54)

0.035 60.010

0.89 60.25

0.700 60.010

17.78 60.25

0.430

(10.92)

0.265
(6.73)

0.125 (3.18) MIN

+0.003
–0.002

0.017
+0.080

–0.050

0.430

0.180 60.030

4.57 60.76

0.085 (2.16)

0.10 60.002
(0.25 60.05)

0.31 60.01

(7.87 60.25)

0.095 (2.41)

0.30

(7.62)

REF

E-20A Package

LCC

0.200 (5.08)
BSC

0.100 (2.54)

0.060 (1.52)

0.358 (9.09)

0.342 (8.69)

0.075
(1.91)

REF

BOTTOM

VIEW

0.015 (0.38)
MIN

PIN 1

0.028 (0.71)

0.022 (0.56)

0.100

(2.54)

BSC

0.055 (1.40)

0.045 (1.14)

0.050
(1.27)

BSC

0.040 REF 3 458
(1.02 3 458)

3 PLACES

0.020 REF 3 458
(0.51 3 458)