INTERSIL ICL8013CCTX

ICL8013
Data Sheet
April 1999
File Number
2863.4
1MHz, Four Quadrant Analog Multiplier
Features
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.
• 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
YOS
Ordering Information
PART
NUMBER
ICL8013BCTX
ICL8013CCTX
10
YIN
MULTIPLICATION
ERROR
(MAX)
TEMP.
RANGE (oC)
±1%
0 to 70
±2%
0 to 70
PKG
PKG.
NO.
10 Pin
T10.B
Metal Can
1
9
ZOS
V+
2
8
GND
ZIN
3
7
XOS
OUTPUT
10 Pin
T10.B
Metal Can
4
6
5
XIN
V-
Functional Diagram
ZIN
XIN
VOLTAGE TO CURRENT
CONVERTER AND
SIGNAL COMPRESSION
XOS
BALANCED
VARIABLE GAIN
AMPLIFIER
OP
AMP
OUT
ZOS
YIN
YOS
VOLTAGE TO CURRENT
CONVERTER
ZIN
1
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Copyright © Intersil Corporation 1999
ICL8013
Absolute Maximum Ratings
Thermal Information
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±18
Input Voltages (XIN, YIN, ZIN, XOS, YOS, ZOS) . . . . . . . . . VSUPPLY
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
Operating Conditions
Temperature Range
ICL8013XC. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC
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.
TA = 25oC, VSUPPLY = ±15V, Gain and Offset Potentiometers Externally Trimmed, Unless Otherwise
Specified
Electrical Specifications
TEST
CONDITIONS
PARAMETER
ICL8013B
ICL8013C
MIN
TYP
MAX
MIN
TYP
MAX
-
XY
10
-
-
XY
10
-
-
-
1.0
-
-
2.0
-
10Z
X
-
-
10Z
X
-
X = -10
-
0.3
-
-
0.3
-
% Full Scale
X = -1
-
1.5
-
-
1.5
-
% Full Scale
X = 0, Y = ±10V
-
-
100
-
-
200
mV
Y = 0, X = ±10V
-
-
100
-
-
150
mV
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
-
1
-
-
1
-
µs
Multiplier Function
Multiplication Error
-10 < X < 10
-10 < Y < 10
Divider Function
Division Error
Feedthrough
UNITS
% Full Scale
Non-Linearity
Settling Time (to ±2% of Final Value)
VlN = ±10V
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
X lnput
-
10
-
-
10
-
MΩ
Y lnput
-
6
-
-
6
-
MΩ
Z lnput
-
36
-
-
36
-
kΩ
X or Y Input
-
-
7.5
-
-
10
µA
Z Input
-
25
-
-
25
-
µA
Input Resistance
VlN = 0V
Input Bias Current
VlN = 0V
2
ICL8013
TA = 25oC, VSUPPLY = ±15V, Gain and Offset Potentiometers Externally Trimmed, Unless Otherwise Specified
(Continued)
Electrical Specifications
ICL8013B
TEST
CONDITIONS
PARAMETER
MIN
TYP
Multiplication Error
-
Output Offset
-
Scale Factor
Quiescent Current
ICL8013C
MAX
MIN
TYP
MAX
UNITS
0.2
-
-
0.2
-
%/%
-
75
-
-
100
mV/V
-
0.1
-
-
0.1
-
%/%
-
3.5
6.0
-
3.5
6.0
mA
Power Supply Variation
THE FOLLOWING SPECIFICATIONS APPLY OVER THE OPERATING TEMPERATURE RANGES
Multiplication Error
-10V < XIN < 10V,
-10V < YIN < 10V
-
2
-
-
3
-
% Full Scale
Accuracy
-
0.06
-
-
0.06
-
%/oC
Output Offset
-
0.2
-
-
0.2
-
mV/oC
Scale Factor
-
0.04
-
-
0.04
-
%/oC
X or Y Input
-
-
5
-
-
10
µA
Z Input
-
-
25
-
-
35
µA
-
-
±10
-
-
±10
V
-
±10
-
-
±10
-
V
Average Temp. Coefficients
Input Bias Current
VIN = 0V
Input Voltage (X, Y, or Z)
RL ≥ 2kΩ
CL < 1000pF
Output Voltage Swing
Schematic Diagram
V+
R2
R8
R16
R23
R27
ZIN
Q1
R9
YIN
R1
XIN
Q14 Q15
Q7 Q8
Q2
Q9
R13
Q21
Q16Q17
R20
Q10
R3
R6
R18
R7
Q22
R21
Q24
Q12
Q11
Q19
R31
R30
R28
Q23
Q18
R10
Q6
R33
ZOS
Q26
COMMON
Q5
Q25
R22
R17
Q4
Q3
C1
Q20
OUTPUT
R29
Q27
YOS
XOS
R32
Q28
R4
R5
V-
3
Q13
R12
R11
R15
R19
R24
R25
R26
ICL8013
Application Information
There are several difficulties with this simple modulator:
Detailed Circuit Description
The fundamental element of the ICL8013 multiplier is the
bipolar differential amplifier of Figure 1.
1. VY must be positive and greater than VD.
2. Some portion of the signal at VX will appear at the output
unless IE = 0.
3. VX must be a small signal for the differential pair to be
linear.
V+
RL
4. The output voltage is not centered around ground.
RL
The first problem relates to the method of converting the VY
voltage to a current to vary the gain of the VX differential 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.
VOUT
VIN
2IE
V-
FIGURE 1. DIFFERENTIAL AMPLIFIER
The small signal differential voltage gain of this circuit is
given by:
V+
IE + ∆I
VIN
1
kT
Substituting r E = ------- = --------gM
qI E
VY
I D ≈ -------- = 2I E and
RY
qR L
V OUT = --------------- ( V X × V Y )
kTR Y
V+
RL
VOUT
VOUT = K (VX x VY) =
qRL
kTRY
(VX x VY)
VIN
2IE
RY
ID
+
VD
-
VY
D1
V-
FIGURE 2. TRANSCONDUCTANCE MULTIPLIER
4
VIN
RE
IE
V-
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
RL
∆I =
IE
qI E R L
 R L
V OUT = V IN  ------- = V IN × ------------------kT
 rE 
Q3
IE - ∆I
∆VOUT
RL
V OUT
A V = ---------------- = ------V IN
rE
FIGURE 3. VOLTAGE TO CURRENT CONVERTER
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 Q1 and Q2 is 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
have a balanced multiplier circuit capable of four quadrant
operation (Figure 5).
ICL8013
V+
V+
RL
IE
∆VOUT = 0
1/ I + ∆
2 E
1/ I - ∆
2 E
RL
RL
IE
R
∆V = K • (VX • VY)
1/ I + ∆
2 E
1/ I - ∆
2 E
+
+
Q1
Q2
Q3
Q1
Q4
Q2
Q3
Q4
VIN
VIN
-
-
IE
IE
RE
VIN
V-
IE
IE
FIGURE 4A. INPUT SIGNAL WITH BALANCED CURRENT
SOURCES ∆VOUT = 0V
V+
RL
RL
∆VOUT = 0
IE
1/ I
2 E
1/ I
2 E
IE
+
Q1
Q2
Q3
Q4
VIN = 0
2IE
IE
V-
FIGURE 4B. NO INPUT SIGNAL WITH UNBALANCED
CURRENT SOURCES ∆VOUT = 0V
V+
RL
3/ I + ∆
2
RL
3/ I - ∆
2
∆VOUT = 0
IE + 2∆
1/ I - ∆
2 E
1/ I - 2∆
2 E
1/ I + ∆
2 E
+
Q1
Q2
Q3
Q4
VIN
-
2IE
IE
V-
FIGURE 4C. INPUT SIGNAL WITH UNBALANCED CURRENT
SOURCES, DIFFERENTIAL OUTPUT VOLTAGE
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.
V-
FIGURE 5. TYPICAL FOUR QUADRANT MULTIPLIERMODULATOR
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/Q8 Q14/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.
X x ID
X x IE
(I - X) IE
(I - X) ID
2 IE
FIGURE 6A. CURRENT GAIN CELL
5
ICL8013
ZIN
V+
R=
IO = XIN • YIN
VOUT
XIN
YIN
MODULATOR
1
10
VOUT =
XIN YIN
10
OP AMP
FIGURE 7A. MULTIPLIER BLOCK DIAGRAM
VVIN
ZIN
V-
FIGURE 6B. VOLTAGE GAIN WITH SIGNAL COMPRESSION
XIN
OUTPUT =
3
6
ICL8013
XIN YIN
4
10
1
YIN
5K
7
10
9
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.
7.5K
XOS YOS ZOS
FIGURE 7B. MULTIPLIER CIRCUIT CONNECTION
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.
Z IN
Therefore I O = X IN • Y IN = ---------- = 10Z IN
R
10Z IN
Since Y IN = V OUT, V OUT = ----------------X IN
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 triangle) to YIN with XIN = 0V, and adjust XOS for minimum output.
3. Apply the sweep signal of Step 2 to XIN with YIN = 0V and
adjust YOS for minimum Output.
4. Readjust ZOS as in Step 1, if necessary.
5. With XIN = 10.0VDC and the sweep signal of Step 2 applied
to YIN, adjust the Gain potentiometer for Output = YIN.
This is easily accomplished with a differential scope plugin (A+B) by inverting one signal and adjusting Gain control
for (Output - YIN) = Zero.
6
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 Output voltage.
4. With ZIN = XIN (and/or ZIN = -XIN) adjust XOS for minimum worst case variation of Output, as XIN is varied from
-10V to -1V.
5. Repeat Steps 2 and 3 if Step 4 required a large initial adjustment.
6. With ZIN = XIN (and/or ZIN = -XIN) 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.
ICL8013
ZIN
R=
IZ
output of the modulator is again forced to equal the current
produced by the Z input.
1
10
VOUT =
XIN
MODULATOR
YIN
10ZIN
I O = X IN × Y IN = ( – V OUT ) 2 = 10Z IN
XIN
OP AMP
IO
V OUT = – 10Z IN
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.
FIGURE 8A. DIVISION BLOCK DIAGRAM
SQUARE ROOT TRIMMING PROCEDURE
XOS YOS ZOS
7
XIN
(0 TO -10V)
6
ZIN
3
10
1. Connect the ICL8013 in the Divider configuration.
9
OUTPUT =
2. Adjust ZOS, YOS, XOS, and Gain using Steps 1 through 6
of Divider Trimming Procedure.
10ZIN
XIN
ICL8013
3. Convert to the Square Root configuration by connecting
XIN to the output and inserting a diode between Pin 4 and
the output node.
4
1
YIN
5K
GAIN
4. With ZIN = 0V adjust ZOS for zero output voltage.
7.5K
Z
R=
FIGURE 8B. DIVISION CIRCUIT CONNECTION
IZ
1
10
XIN
Squaring
VOUT = -√10ZIN
MODULATOR
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).
ZIN
R=
IO = XIN • YIN
FIGURE 10A. SQUARE ROOT BLOCK DIAGRAM
1
10
XOS YOS ZOS
XIN
VOUT =
X
OP AMP
IO = VO2
YIN
OP AMP
XIN2
7
10
10
9
XIN
YIN
(0V TO + 10V) 6
ZIN
3
YIN
1
FIGURE 9A. SQUARER BLOCK DIAGRAM
1N4148 OUTPUT = -√10Z
IN
ICL8013
4
GAIN
XIN
5kΩ
SCALE
FACTOR
ADJUST
5K
7.5K
3
OUTPUT =
6
ICL8013
1
XIN2
10
7.5kΩ
7
10
9
XOS YOS ZOS
FIGURE 9B. SQUARER CIRCUIT CONNECTION
Square Root
Tying the X and Y inputs together and using overall feedback
from the op amp results in the square root function. The
7
FIGURE 10B. ACTUAL CIRCUIT CONNECTION
4
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.
ICL8013
Z
3
6
INPUT
XY
4 OUTPUT = 10
ICL8013
V+
1
GAIN
CONTROL
VOLTAGE
5K
7.5K
7
10
9
XOS
20K
YOS
20K
20K
ZOS
XOS YOS ZOS
V-
FIGURE 12. POTENTIOMETERS FOR TRIMMING OFFSET AND
FEEDTHROUGH
FIGURE 11. VARIABLE GAIN AMPLIFIER
Typical Performance Curves
NONLINEARITY (% OF FULL SCALE)
100
0
0
AMPLITUDE
AMPLITUDE (dB)
PHASE
10
-20
15
-30
-40
20
25
1K
PHASE (DEGREES)
-10
5
10K
100K
FREQUENCY (Hz)
-50
10M
1M
10
1
X-INPUT
Y-INPUT
0.1
0.01
100
FIGURE 13. FREQUENCY RESPONSE
1K
10K
FREQUENCY (Hz)
100K
FIGURE 14. NONLINEARITY vs FREQUENCY
-10
FEEDTHROUGH (dB)
-20
X = 0, Y = 20VP-P
-30
-40
-50
-60
Y = 0, X = 20VP-P
-70
1K
10K
100K
1M
10M
FREQUENCY (Hz)
FIGURE 15. FEEDTHROUGH vs FREQUENCY
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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
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