ICL8013BCTX - Intersil Corporation

File Number 2863.5

CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.

ICL8013

1MHz, Four Quadrant Analog Multiplier

The ICL8013 is a four quadrant analog multiplier whose

output is proportional to the algebraic product of two input

signals. Feedback around an internal op amp provides level

shifting and can be used to generate division and square

root functions. A simple arrangement of potentiometers may

be used to trim gain accuracy, offset voltage and

feedthrough performance. The high accuracy, wide

bandwidth, and increased versatility of the ICL8013 make it

ideal for all multiplier applications in control and

instrumentation systems. Applications include RMS

measuring equipment, frequency doublers, balanced

modulators and demodulators, function generators, and

voltage controlled ampliﬁers.

Features

• Accuracy. . . . . . . . . . . . . . . . . . . . . . . . ±1% (“B” Version)

• Input Voltage Range. . . . . . . . . . . . . . . . . . . . . . . . . ±10V

• Bandwidth. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1MHz

• Uses Standard ±15V Supplies

• Built-In Op Amp Provides Level Shifting, Division and

Square Root Functions

Pinout ICL8013

(METAL CAN)

TOP VIEW

Functional Diagram

Part Number Information

PART

NUMBER

MULTIPLI-

CATION

ERROR

(MAX) TEMP.

RANGE (oC) PKG PKG.

NO.

ICL8013BCTX ±1% 0 to 70 10 Pin

Metal Can T10.B

ICL8013CCTX ±2% 0 to 70 10 Pin

Metal Can T10.B

YOS

GND

V-

OUTPUT

V+ 2

ZOS

XOS

XIN

ZIN

YIN

VOLTAGE TO CURRENT

CONVERTER AND

SIGNAL COMPRESSION

BALANCED

VARIABLE GAIN

AMPLIFIER

AMP OUT

VOLTAGE TO CURRENT

CONVERTER

ZOS

ZIN

YOS

YIN

XIN

XOS

ZIN

Data Sheet November 2000

[ /Title

(ICL80

13)

/Sub-

ject (

1MHz,

Four

Quad-

rant

Ana-

log

Multi-

plier

)

/Autho

r ()

/Key-

words

(Inter-

sil

Corpo-

ration,

semi-

con-

ductor,

analog

multi-

plier,

four

quad-

rant,

high

accu-

racy,

low

power,

modu-

lator,

FOR A POSSIBLE SUBSTITUTE PRODUCT

call Central Applications 1-888-INTERSIL

or email: centapp@intersil.com

OBSOLETE PRODUCT

Absolute Maximum Ratings Thermal Information

Supply Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±18

Input Voltages (XIN, YIN, ZIN, XOS, YOS, ZOS) . . . . . . . . . VSUPPLY

Operating Conditions

Temperature Range

ICL8013XC. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC

Thermal Resistance (Typical, Note 1) θJA (oC/W) θJC (oC/W)

Metal Can Package . . . . . . . . . . . . . . . 160 75

Maximum Junction Temperature (Metal Can Package) . . . . . . .175oC

Maximum Storage Temperature Range. . . . . . . . . . -65oC to 150oC

Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . 300oC

CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the

device at these or any other conditions above those indicated in the operational sections of this speciﬁcation is not implied.

NOTE:

1. θJA is measured with the component mounted on an evaluation PC board in free air.

Electrical Speciﬁcations TA= 25oC, VSUPPLY = ±15V, Gain and Offset Potentiometers Externally Trimmed, Unless Otherwise

Speciﬁed

PARAMETER TEST

CONDITIONS

ICL8013B ICL8013C

UNITSMIN TYP MAX MIN TYP MAX

Multiplier Function - XY

10 --XY

10 -

Multiplication Error -10 < X < 10

-10 < Y < 10 - - 1.0 - - 2.0 % Full Scale

Divider Function - 10Z

X- - 10Z

X-

Division Error X = -10 - 0.3 - - 0.3 - % Full Scale

X = -1 - 1.5 - - 1.5 - % Full Scale

Feedthrough X = 0, Y = ±10V - - 100 - - 200 mV

Y = 0, X = ±10V - - 100 - - 150 mV

Non-Linearity

X Input X = 20VP-P

Y= ±10VDC -±0.5 - - ±0.8 - %

Y Input Y = 20VP-P

X = ±10VDC -±0.2 - - ±0.3 - %

Frequency Response Small Signal

Bandwidth (-3dB) - 1.0 - - 1.0 - MHz

Full Power Bandwidth - 750 - - 750 - kHz

Slew Rate - 45 - - 45 - V/µs

1% Amplitude Error - 75 - - 75 - kHz

1% Vector Error (0.5o Phase Shift) - 5 - - 5 - kHz

Settling Time (to ±2% of Final Value) VlN = ±10V - 1 - - 1 - µs

Overload Recovery (to ±2% of Final Value) VlN = ±10V - 1 - - 1 - µs

Output Noise 5Hz to 10kHz - 0.6 - - 0.6 - mVRMS

5Hz to 5MHz - 3 - - 3 - mVRMS

Input Resistance VlN = 0V

X lnput - 10 - - 10 - MΩ

Y lnput - 6 - - 6 - MΩ

Z lnput - 36 - - 36 - kΩ

Input Bias Current VlN = 0V

X or Y Input - - 7.5 - - 10 µA

Z Input - 25 - - 25 - µA

ICL8013

Schematic Diagram

Power Supply Variation

Multiplication Error - 0.2 - - 0.2 - %/%

Output Offset - - 75 - - 100 mV/V

Scale Factor - 0.1 - - 0.1 - %/%

Quiescent Current - 3.5 6.0 - 3.5 6.0 mA

THE FOLLOWING SPECIFICATIONS APPLY OVER THE OPERATING TEMPERATURE RANGES

Multiplication Error -10V < XIN < 10V,

-10V < YIN < 10V - 2 - - 3 - % Full Scale

Average Temp. Coefficients

Accuracy - 0.06 - - 0.06 - %/oC

Output Offset - 0.2 - - 0.2 - mV/oC

Scale Factor - 0.04 - - 0.04 - %/oC

Input Bias Current VIN = 0V

X or Y Input - - 5 - - 10 µA

Z Input - - 25 - - 35 µA

Input Voltage (X, Y, or Z) - - ±10 - - ±10 V

Output Voltage Swing RL≥ 2kΩ

CL < 1000pF -±10 - - ±10 - V

Electrical Speciﬁcations TA=25

oC, VSUPPLY =±15V, Gain and Offset Potentiometers Externally Trimmed, Unless Otherwise Speciﬁed

(Continued)

PARAMETER TEST

CONDITIONS

ICL8013B ICL8013C

UNITSMIN TYP MAX MIN TYP MAX

Q1Q2

Q3Q4

COMMON

YIN

XIN

V+

V-

Q5Q6

R4R5

Q28

Q7Q8Q14 Q15

Q10

R13

R6R7

R10

Q11 Q12

Q13

R12 R15

R11 R19

R18

R17

YOS

XOS

R20 R22

R16

R2R8R23

R24 R25 R26

R21

Q19

Q18

Q20

Q16

Q24

Q23

Q22

Q26

C1Q21

R27

Q25

R31 R30

R28

R29

Q27

R33

OUTPUT

ZIN

Q17

R32

ZOS

ICL8013

Application Information

Detailed Circuit Description

The fundamental element of the ICL8013 multiplier is the

bipolar differential ampliﬁer of Figure 1.

The small signal differential voltage gain of this circuit is

given by:

The output voltage is thus proportional to the product of the

input voltage VlN and the emitter current IE. In the simple

transconductance multiplier of Figure 2, a current source

comprising Q3, D1, and RY is used. If VY is large compared

with the drop across D1, then

There are several difﬁculties with this simple modulator:

1. VY must be positive and greater than VD.

2. Some portion of the signal at VXwill appear at the output

unless IE = 0.

3. VXmust be a small signal for the differential pair to be

linear.

4. The output voltage is not centered around ground.

The ﬁrst problem relates to the method of converting the VY

voltage to a current to vary the gain of the VXdifferential pair.

A better method, Figure 3, uses another differential pair but

with considerable emitter degeneration. In this circuit the

differential input voltage appears across the common emitter

resistor, producing a current which adds or subtracts from

the quiescent current in either collector. This type of voltage

to current converter handles signals from 0V to ±10V with

excellent linearity.

The second problem is called feedthrough; i.e., the product

of zero and some ﬁnite Input signal does not produce zero

output voltage. The circuit whose operation is illustrated by

Figures 4A, 4B, and 4C overcomes this problem and forms

the heart of many multiplier circuits in use today.

This circuit is basically two matched differential pairs with

cross coupled collectors. Consider the case shown in Figure

4A of exactly equal current sources basing the two pairs.

With a small positive signal at VlN, the collector current of Q1

and Q4 will increase but the collector currents of Q2 and Q3

will decrease by the same amount. Since the collectors are

cross coupled the current through the load resistors remains

unchanged and independent of the VlN input voltage.

In Figure 4B, notice that with VIN = 0 any variation in the ratio

of biasing current sources will produce a common mode

voltage across the load resistors. The differential output

voltage will remain zero. In Figure 4C we apply a differential

input voltage with unbalanced current sources. If IE1 is twice

IE2 the gain of differential pair Q1and Q2is twice the gain of

pair Q3 and Q4. Therefore, the change in cross coupled

collector currents will be unequal and a differential output

voltage will result. By replacing the separate biasing current

sources with the voltage to current converter of Figure 3 we

hav e a balanced m ultiplier circuit capab le of f our quadr ant

operation (Figure 5).

2IE

VIN

VOUT

V+

V-

FIGURE 1. DIFFERENTIAL AMPLIFIER

AVVOUT

VIN

----------------RL

-------==

Substituting rE1

------- kT

qIE

---------==

VOUT VIN RL

-------





 VIN qIERL

-------------------

×==

IDVY

--------

≈2IEand=

VOUT qRL

kTRY

--------------- VXVY

×()=

2IE

VIN

VOUT

V+

V-

VDD1

qRL

kTRY(VX x VY)

VOUT = K (VX x VY) =

FIGURE 2. TRANSCONDUCTANCE MULTIPLIER

IE + ∆I

IE - ∆I

VIN

∆VOUT

V+

V-

∆I = VIN

FIGURE 3. VOLTAGE TO CURRENT CONVERTER

ICL8013

This circuit of Figure 5 still has the problem that the input

voltage VIN must be small to keep the differential ampliﬁer in

the linear region. To be able to handle large signals, we need

an amplitude compression circuit.

Figure 2 showed a current source formed by relying on the

matching characteristics of a diode and the emitter base

junction of a transistor. Extension of this idea to a differential

circuit is shown in Figure 6A. In a differential pair, the input

voltage splits the biasing current in a logarithmic ratio. (The

usual assumption of linearity is useful only for small signals.)

Since the input to the differential pair in Figure 6A is the

difference in voltage across the two diodes, which in turn is

proportional to the log of the ratio of drive currents, it follows

that the ratio of diode currents and the ratio of collector

currents are linearly related and independent of amplitude. If

we combine this circuit with the voltage to current converter

of Figure 3, we have Figure 6B. The output of the differential

ampliﬁer is now proportional to the input voltage over a large

dynamic range, thereby improving linearity while minimizing

drift and noise factors.

The complete schematic is shown after the Electrical

Speciﬁcations Table. The differential pair Q3 and Q4 form a

voltage to current converter whose output is compressed in

collector diodes Q1 and Q2. These diodes drive the

balanced cross-coupled differential ampliﬁer Q7/Q8Q14/Q15.

The gain of these ampliﬁers is modulated by the voltage to

current converter Q9 and Q10. Transistors Q5, Q6, Q11, and

Q12 are constant current sources which bias the voltage to

current converter. The output ampliﬁer comprises transistors

Q16 through Q27.

VIN

∆VOUT = 0

V+

V-

1/2 IE + ∆

1/2 IE - ∆

Q1Q2Q3Q4

1/2 IE - ∆

1/2 IE + ∆

IEIE

FIGURE 4A. INPUT SIGNAL WITH BALANCED CURRENT

SOURCES ∆VOUT = 0V

VIN = 0

∆VOUT = 0

V+

2IE

V-

1/2 IE

Q1Q2Q3Q4

FIGURE 4B. NO INPUT SIGNAL WITH UNBALANCED

CURRENT SOURCES ∆VOUT = 0V

VIN

∆VOUT = 0

V+

2IE

V-

1/2 IE + ∆

1/2 IE - ∆

Q1Q2Q3Q4

1/2 IE -2∆

IE + 2∆

3/2I + ∆3/2I - ∆

FIGURE 4C. INPUT SIGNAL WITH UNBALANCED CURRENT

SOURCES, DIFFERENTIAL OUTPUT VOLTAGE

VIN

∆V = K • (VX • VY)

V+

V-

Q1Q2Q3Q4

VIN

FIGURE 5. TYPICAL FOUR QUADRANT MULTIPLIER-

MODULATOR

X x IDX x IE(I - X) IE(I - X) ID

2 IE

FIGURE 6A. CURRENT GAIN CELL

ICL8013

Deﬁnition of Terms

Multiplication/Division Error: This is the basic accuracy

speciﬁcation. It includes terms due to linearity, gain, and

offset errors, and is expressed as a percentage of the full

scale output.

Feedthrough: With either input at zero, the output of an

ideal multiplier should be zero regardless of the signal

applied to the other input. The output seen in a non-ideal

multiplier is known as the feedthrough.

Nonlinearity: The maximum deviation from the best

straight line constructed through the output data, expressed

as a percentage of full scale. One input is held constant and

the other swept through it nominal range. The nonlinearity is

the component of the total multiplication/division error which

cannot be trimmed out.

Typical Applications

Multiplication

In the standard multiplier connection, the Z terminal is

connected to the op amp output. All of the modulator output

current thus ﬂows through the feedback resistor R27 and

produces a proportional output voltage.

MULTIPLIER TRIMMING PROCEDURE

1. Set XIN = YIN = 0V and adjust ZOS for zero Output.

2. Apply a ±10V low frequency (≤100Hz) sweep (sine or trian-

gle) to YIN with XIN = 0V, and adjust XOS f or minimum out-

put.

3. Applythe sweepsignalofStep 2 to XIN withYIN = 0V and

adjust YOS for minimum Output.

4. Readjust ZOS as in Step 1, if necessary.

5. WithXIN=10.0VDCandthesweepsignalofStep2applied

to YIN, adjust the Gain potentiometer f or Output = YIN.

This is easily accomplished with a diff erential scope plug-

in (A+B) by inverting one signal and adjusting Gain control

f or (Output - YIN) = Zero.

Division

If the Z terminal is used as an input, and the output of the op

amp connected to the Y input, the device functions as a

divider. Since the input to the op amp is at virtual ground,

and requires negligible bias current, the overall feedback

forces the modulator output current to equal the current

produced by Z.

Note that when connected as a divider, the X input must be a

negative voltage to maintain overall negative feedback.

DIVIDER TRIMMING PROCEDURE

1. Set trimming potentiometers at mid-scale by adjusting

voltage on pins 7, 9 and 10 (XOS, YOS, ZOS) for 0V.

2. With ZIN = 0V, trim ZOS to hold the Output constant, as

XIN is varied from -10V through -1V.

3. With ZIN = 0V and XIN = -10.0V adjust YOS for zero Out-

put voltage.

4. With ZIN = XIN (and/or ZIN = -XIN) adjust XOS for mini-

mumworst casevariationof Output, as XIN is variedfrom

-10V to -1V.

5. Repeat Steps 2 and 3 if Step 4 required a large initial ad-

justment.

6. With ZIN =X

IN (and/or ZIN =-X

IN) adjust the gain control

until the output is the closest average around +10.0V

(-10V for ZIN = -XIN) as XIN is varied from -10V to -3V.

VIN

V+

VOUT

V-

FIGURE 6B. VOLTAGE GAIN WITH SIGNAL COMPRESSION

OP AMP

MODULATOR

XIN

YIN

ZIN

IO = XIN • YIN

R =

VOUT =

10 XIN YIN

FIGURE 7A. MULTIPLIER BLOCK DIAGRAM

ICL8013

ZIN

XIN

YIN

7.5K

710 9

XOS YOS ZOS

OUTPUT = XIN YIN

FIGURE 7B. MULTIPLIER CIRCUIT CONNECTION

Therefore IOXIN YIN

•ZIN

----------10ZIN

===

Since YIN VOUT VOUT

,10ZIN

XIN

-----------------==

ICL8013

Squaring

The squaring function is achieved by simply multiplying with

the two inputs tied together. The squaring circuit may also be

used as the basis for a frequency doubler since cos2ωt=1/2

(cos 2ωt + 1).

Square Root

Tying the X and Y inputs together and using overall feedback

from the op amp results in the square root function. The

output of the modulator is again forced to equal the current

produced by the Z input.

The output is a negative voltage which maintains overall

negative feedback. A diode in series with the op amp output

prevents the latchup that would otherwise occur for negative

input voltages.

SQUARE ROOT TRIMMING PROCEDURE

1. Connect the ICL8013 in the Divider conﬁguration.

2. Adjust ZOS,Y

OS,X

OS, and Gain using Steps 1 through 6

of Divider Trimming Procedure.

3. Convert to the Square Root conﬁguration by connecting

XIN tothe output andinserting a diodebetweenPin 4and

the output node.

4. With ZIN = 0V adjust ZOS for zero output voltage.

Variable Gain Ampliﬁer

Most applications for the ICL8013 are straight forward

variations of the simple arithmetic functions described

above. Although the circuit description frequently disguises

the fact, it has already been shown that the frequency

doubIer is nothing more than a squaring circuit. Similarly the

variable gain ampliﬁer is nothing more than a multiplier, with

the input signal applied at the X input and the control voltage

applied at the Y input.

OP AMP

MODULATOR

XIN

YIN

ZIN

IZR =

VOUT =

10 10ZIN

XIN

FIGURE 8A. DIVISION BLOCK DIAGRAM

ICL8013

ZIN

XIN

YIN 5K

7.5K

710 9

XOS YOS ZOS

OUTPUT = 10ZIN

XIN

GAIN

(0 TO -10V)

FIGURE 8B. DIVISION CIRCUIT CONNECTION

OP AMP

XIN

YIN

ZIN

IO = XIN • YIN

R =

VOUT =

XIN2

FIGURE 9A. SQUARER BLOCK DIAGRAM

ICL8013

XIN

7.5kΩ710 9

XOS YOS ZOS

OUTPUT = XIN2

5kΩ

SCALE

FACTOR

ADJUST

FIGURE 9B. SQUARER CIRCUIT CONNECTION

IOXIN YIN

×VOUT

–()

210ZIN

== =

VOUT 10ZIN

–=

OP AMP

MODULATOR

XIN

YIN

IZR =

VOUT = -√10ZIN

IO = VO2

FIGURE 10A. SQUARE ROOT BLOCK DIAGRAM

ICL8013

ZIN

XIN

YIN

7.5K

710 9

XOS YOS ZOS

OUTPUT = -√10ZIN

GAIN

(0V T O + 10V) 1N4148

FIGURE 10B. ACTUAL CIRCUIT CONNECTION

ICL8013

All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certiﬁcation.

Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time with-

out notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and

reliable. However, no responsibility is assumed by Intersil or its subsidiaries 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 Intersil or its subsidiaries.

For information regarding Intersil Corporation and its products, see web site http://www.intersil.com

ICL8013

INPUT

GAIN

7.5K

710 9

XOS YOS ZOS

OUTPUT = XY

CONTROL

VOLTAGE

FIGURE 11. VARIABLE GAIN AMPLIFIER

XOS YOS ZOS

V+

V-

20K

20K20K

FIGURE12. POTENTIOMETERSFORTRIMMINGOFFSETAND

FEEDTHROUGH

Typical Performance Curves

FIGURE 13. FREQUENCY RESPONSE FIGURE 14. NONLINEARITY vs FREQUENCY

FIGURE 15. FEEDTHROUGH vs FREQUENCY

AMPLITUDE (dB)

FREQUENCY (Hz)

PHASE (DEGREES)

PHASE

AMPLITUDE

1K 10K 100K 1M 10M

-50

-10

-20

-30

-40

FREQUENCY (Hz)

1K 10K 100K100

100

0.1

0.01

NONLINEARITY (% OF FULL SCALE)

Y-INPUT

X-INPUT

FREQUENCY (Hz)

1K 10K 100K 1M 10M

FEEDTHROUGH (dB)

-10

-20

-30

-40

-50

-60

-70

X = 0, Y = 20VP-P

Y = 0, X = 20VP-P

ICL8013