AD834JR-REEL Analog Devices Inc, AD834JR-REEL Datasheet - Page 11

AD834JR-REEL

Manufacturer Part Number

AD834JR-REEL

Description

IC MULTIPLIER 4-QUADRANT 8-SOIC

Manufacturer

Analog Devices Inc

Datasheet

1.AD834JRZ.pdf (20 pages)

Specifications of AD834JR-REEL

Rohs Status

RoHS non-compliant

Function

Analog Multiplier

Number Of Bits/stages

4-Quadrant

Package / Case

8-SOIC (3.9mm Width)

Number Of Elements

Output Type

Differential

Power Supply Requirement

Dual

Single Supply Voltage (typ)

Not RequiredV

Single Supply Voltage (min)

Not RequiredV

Single Supply Voltage (max)

Not RequiredV

Dual Supply Voltage (typ)

±5V

Dual Supply Voltage (min)

±4V

Dual Supply Voltage (max)

±9V

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Pin Count

Package Type

SOIC

Lead Free Status / RoHS Status

Not Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

AD834JR-REEL

Quantity:

340

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

AD834JR-REEL7

Manufacturer:

ANALOGDEVICES

Quantity:

6 020

Current page: 11 of 20
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THEORY OF OPERATION

Figure 11 is a functional equivalent of the AD834. There are three

differential signal interfaces: the two voltage inputs (X = X1 −

X2 and Y = Y1 − Y2), and the current output (W) which flows

in the direction shown in Figure 11 when X and Y are positive.

The outputs (W1 and W2) each have a standing current of

typically 8.5 mA.

The input voltages are first converted to differential currents

that drive the translinear core. The equivalent resistance of the

voltage-to-current (V-I) converters is about 285 Ω, which results

in low input related noise and drift. However, the low full-scale

input voltage results in relatively high nonlinearity in the V-I

converters. This is significantly reduced by the use of distortion

cancellation circuits, which operate by Kelvin sensing the voltages

generated in the core—an important feature of the AD834.

The current mode output of the core is amplified by a special

cascode stage that provides a current gain of nominally × 1.6,

trimmed during manufacturing to set up the full-scale output

current of ±4 mA. This output appears at a pair of open collec-

tors that must be supplied with a voltage slightly above the

voltage on Pin 6. As shown in Figure 12, this can be arranged

by inserting a resistor in series with the supply to Pin 6 and

taking the load resistors to the full supply. With R3 = 60 Ω, the

voltage drop across it is about 600 mV. Using two 50 Ω load

resistors, the full-scale differential output voltage is ±400 mV.

For best performance, the voltage on the output open-collectors

(Pin 4 and Pin 5) must be higher than the voltage on Pin 6 by

about 200 mV, as shown in Figure 12.

The full bandwidth potential of the AD834 can be realized only

when very careful attention is paid to grounding and decoupling.

The device must be mounted close to a high quality ground

plane and all lead lengths must be extremely short, in keeping

with UHF circuit layout practice. In fact, the AD834 shows

useful response to well beyond 1 GHz, and the actual upper

frequency in a typical application is usually determined by the

MULTIPLIER CORE

CANCELLATION

X-DISTORTION

Y-DISTORTION

V-I

Figure 11. Functional Block Diagram

AD834

AMPLIFIER

CURRENT

–V

(W)

8.5mA

±4mA

Rev. E | Page 11 of 20

care with which the layout is affected. Note that R4 (in series

with the −V

voltage drop of about 150 mV. It is made large enough to reduce

the Q of the resonant circuit formed by the supply lead and the

decoupling capacitor. Slightly larger values can be used, particu-

larly when using higher supply voltages. Alternatively, lossy RF

chokes or ferrite beads on the supply leads may be used.

For best performance, use termination resistors at the inputs, as

shown in Figure 12. Note that although the resistive component

of the input impedance is quite high (about 25 kΩ), the input

bias current of typically 45 μA can generate significant offset

voltages if not compensated. For example, with a source and

termination resistance of 50 Ω (net source of 25 Ω) the offset is

25 Ω × 45 μA = 1.125 mV. The offset can be almost fully cancelled

by including (in this example) another 25 Ω resistor in series with

the unused input. (In Figure 12, a 25 Ω resistor would be added

from X1 to GND and Y2 to GND.) To minimize crosstalk, ground

the input pins closest to the output (X1 and Y2); the effect is

merely to reverse the phase of the X input and thus alter the

polarity of the output.

TRANSFER FUNCTION

The Output Current W is the linear product of input voltages (X

and Y) divided by (1 V)

4 mA:

With the understanding that the inputs are specified in volts,

the following simplified expression can be used:

Alternatively, the full transfer function can be written as

X-INPUT

Y-INPUT

±1V FS

W = (XY) 4 mA

W =

Figure 12. Basic Connections for Wideband Operation

( )

TERMINATION

RESISTOR

TERMINATION

RESISTOR

supply) carries about 30 mA and thus introduces a

250

AD834

Y2 –V

X1 +V

4.7Ω

and multiplied by the scaling current of

62Ω

CERAMIC

1µF

49.9Ω

W OUTPUT

±400mV FS

+5V

–5V

AD834

AD834JR-REEL Analog Devices Inc, AD834JR-REEL Datasheet - Page 11

AD834JR-REEL

Specifications of AD834JR-REEL

Available stocks

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