CA3140, CA3140A

®

Data Sheet

July 11, 2005

4.5MHz, BiMOS Operational Amplifier with
MOSFET Input/Bipolar Output
The CA3140A and CA3140 are integrated circuit operational
amplifiers that combine the advantages of high voltage
PMOS transistors with high voltage bipolar transistors on a
single monolithic chip.
The CA3140A and CA3140 BiMOS operational amplifiers
feature gate protected MOSFET (PMOS) transistors in the
input circuit to provide very high input impedance, very low
input current, and high speed performance. The CA3140A
and CA3140 operate at supply voltage from 4V to 36V
(either single or dual supply). These operational amplifiers
are internally phase compensated to achieve stable
operation in unity gain follower operation, and additionally,
have access terminal for a supplementary external capacitor
if additional frequency roll-off is desired. Terminals are also
provided for use in applications requiring input offset voltage
nulling. The use of PMOS field effect transistors in the input
stage results in common mode input voltage capability down
to 0.5V below the negative supply terminal, an important
attribute for single supply applications. The output stage
uses bipolar transistors and includes built-in protection
against damage from load terminal short circuiting to either
supply rail or to ground.
The CA3140A and CA3140 are intended for operation at supply
voltages up to 36V (±18V).

FN957.10

Features
• MOSFET Input Stage
- Very High Input Impedance (ZIN) -1.5TΩ (Typ)
- Very Low Input Current (Il) -10pA (Typ) at ±15V
- Wide Common Mode Input Voltage Range (VlCR) - Can be
Swung 0.5V Below Negative Supply Voltage Rail
- Output Swing Complements Input Common Mode
Range
• Directly Replaces Industry Type 741 in Most Applications
• Pb-Free Plus Anneal Available (RoHS Compliant)

Applications
• Ground-Referenced Single Supply Amplifiers in
Automobile and Portable Instrumentation
• Sample and Hold Amplifiers
• Long Duration Timers/Multivibrators
(µseconds-Minutes-Hours)
• Photocurrent Instrumentation
• Peak Detectors
• Active Filters
• Comparators
• Interface in 5V TTL Systems and Other Low
Supply Voltage Systems
• All Standard Operational Amplifier Applications
• Function Generators
• Tone Controls
• Power Supplies
• Portable Instruments
• Intrusion Alarm Systems

Pinout
CA3140 (PDIP, SOIC)
TOP VIEW

1

OFFSET
NULL

1

INV. INPUT

2

NON-INV.
INPUT

3

V-

4

+

8

STROBE

7

V+

6

OUTPUT

5

OFFSET
NULL

CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright Harris Corporation 1998, Copyright Intersil Americas Inc. 2002, 2004, 2005. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.

CA3140, CA3140A

Ordering Information
PART NUMBER
(BRAND)

TEMP.
RANGE (°C)

PACKAGE

PKG.
DWG. #

CA3140AE

-55 to 125

8 Ld PDIP

E8.3

CA3140AEZ*
(See Note)

-55 to 125

8 Ld PDIP
(Pb-free)

E8.3

CA3140AM
(3140A)

-55 to 125

8 Ld SOIC

M8.15

CA3140AM96
(3140A)

-55 to 125

8 Ld SOIC Tape and Reel

CA3140AMZ
(3140A) (See Note)

-55 to 125

8 Ld SOIC
(Pb-free)

CA3140AMZ96
(3140A) (See Note)

-55 to 125

8 Ld SOIC Tape and Reel
(Pb-free)

CA3140E

-55 to 125

8 Ld PDIP

E8.3

CA3140EZ*
(See Note)

-55 to 125

8 Ld PDIP
(Pb-free)

E8.3

CA3140M
(3140)

-55 to 125

8 Ld SOIC

M8.15

CA3140M96
(3140)

-55 to 125

8 Ld SOIC Tape and Reel

CA3140MZ
(3140) (See Note)

-55 to 125

8 Ld SOIC
(Pb-free)

CA3140MZ96
(3140) (See Note)

-55 to 125

8 Ld SOIC Tape and Reel
(Pb-free)

M8.15

M8.15

*Pb-free PDIPs can be used for through hole wave solder
processing only. They are not intended for use in Reflow solder
processing applications.
NOTE: Intersil Pb-free products employ special Pb-free material
sets; molding compounds/die attach materials and 100% matte tin
plate termination finish, which are RoHS compliant and compatible
with both SnPb and Pb-free soldering operations. Intersil Pb-free
products are MSL classified at Pb-free peak reflow temperatures
that meet or exceed the Pb-free requirements of IPC/JEDEC J STD020.

2

FN957.10
July 11, 2005

CA3140, CA3140A
Absolute Maximum Ratings

Thermal Information

DC Supply Voltage (Between V+ and V- Terminals) . . . . . . . . . 36V
Differential Mode Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . 8V
DC Input Voltage . . . . . . . . . . . . . . . . . . . . . . (V+ +8V) To (V- -0.5V)
Input Terminal Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1mA
Output Short Circuit Duration∞ (Note 2) . . . . . . . . . . . . . . Indefinite

Thermal Resistance (Typical, Note 1)
θJA (oC/W) θJC (oC/W)
PDIP Package*. . . . . . . . . . . . . . . . . . .
115
N/A
SOIC Package . . . . . . . . . . . . . . . . . . .
165
N/A
Maximum Junction Temperature (Plastic Package) . . . . . . . 150oC
Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . 300oC
(SOIC - Lead Tips Only)

Operating Conditions
Temperature Range . . . . . . . . . . . . . . . . . . . . . . . . . -55oC to 125oC

*Pb-free PDIPs can be used for through hole wave solder processing only. They are not intended for use in Reflow solder processing
applications.
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.

NOTES:
1. θJA is measured with the component mounted on a low effective thermal conductivity test board in free air. See Tech Brief TB379 for details
2. Short circuit may be applied to ground or to either supply.
VSUPPLY = ±15V, TA = 25oC

Electrical Specifications

TYPICAL VALUES
PARAMETER

SYMBOL

Input Offset Voltage Adjustment Resistor

TEST CONDITIONS
Typical Value of Resistor
Between Terminals 4 and 5 or 4 and 1 to
Adjust Max VIO

CA3140

CA3140A

UNITS

4.7

18

kΩ

Input Resistance

RI

1.5

1.5

TΩ

Input Capacitance

CI

4

4

pF

Output Resistance

RO

60

60

Ω

Equivalent Wideband Input Noise Voltage
(See Figure 27)

eN

BW = 140kHz, RS = 1MΩ

48

48

µV

Equivalent Input Noise Voltage (See Figure 35)

eN

RS = 100Ω

f = 1kHz

40

40

nV/√Hz

f = 10kHz

12

12

nV/√Hz

IOM+

Source

40

40

mA

IOM-

Sink

18

18

mA

Short Circuit Current to Opposite Supply

Gain-Bandwidth Product, (See Figures 6, 30)

fT

4.5

4.5

MHz

Slew Rate, (See Figure 31)

SR

9

9

V/µs

220

220

µA

Rise Time

0.08

0.08

µs

Overshoot

10

10

%

To 1mV

4.5

4.5

µs

To 10mV

1.4

1.4

µs

Sink Current From Terminal 8 To Terminal 4 to
Swing Output Low
Transient Response (See Figure 28)

tr
OS

Settling Time at 10VP-P, (See Figure 5)

tS

RL = 2kΩ
CL = 100pF
RL = 2kΩ
CL = 100pF
Voltage Follower

For Equipment Design, at VSUPPLY = ±15V, TA = 25oC, Unless Otherwise Specified

Electrical Specifications

CA3140
PARAMETER

CA3140A

SYMBOL

MIN

TYP

MAX

MIN

TYP

MAX

UNITS

Input Offset Voltage

|VIO|

-

5

15

-

2

5

mV

Input Offset Current

|IIO|

-

0.5

30

-

0.5

20

pA

II

-

10

50

-

10

40

pA

Input Current

3

FN957.10
July 11, 2005

CA3140, CA3140A
For Equipment Design, at VSUPPLY = ±15V, TA = 25oC, Unless Otherwise Specified (Continued)

Electrical Specifications

CA3140
PARAMETER
Large Signal Voltage Gain (Note 3)
(See Figures 6, 29)
Common Mode Rejection Ratio
(See Figure 34)

CA3140A

SYMBOL

MIN

TYP

MAX

MIN

TYP

MAX

UNITS

AOL

20

100

-

20

100

-

kV/V

86

100

-

86

100

-

dB

-

32

320

-

32

320

µV/V

70

90

-

70

90

-

dB

CMRR

Common Mode Input Voltage Range (See Figure 8)

VICR

-15

-15.5 to +12.5

11

-15

-15.5 to +12.5

12

V

Power-Supply Rejection Ratio,
∆VIO/∆VS (See Figure 36)

PSRR

-

100

150

-

100

150

µV/V

76

80

-

76

80

-

dB

Max Output Voltage (Note 4)
(See Figures 2, 8)

VOM+

+12

13

-

+12

13

-

V

VOM-

-14

-14.4

-

-14

-14.4

-

V

Supply Current (See Figure 32)

I+

-

4

6

-

4

6

mA

Device Dissipation

PD

-

120

180

-

120

180

mW

∆VIO/∆T

-

8

-

-

6

-

µV/oC

Input Offset Voltage Temperature Drift
NOTES:
3. At VO = 26VP-P , +12V, -14V and RL = 2kΩ.
4. At RL = 2kΩ.

For Design Guidance At V+ = 5V, V- = 0V, TA = 25oC

Electrical Specifications

TYPICAL VALUES
PARAMETER

SYMBOL

CA3140

CA3140A

UNITS

Input Offset Voltage

|VIO|

5

2

mV

Input Offset Current

|IIO|

0.1

0.1

pA

Input Current

II

2

2

pA

Input Resistance

RI

1

1

TΩ

AOL

100

100

kV/V

100

100

dB

32

32

µV/V

90

90

dB

-0.5

-0.5

V

2.6

2.6

V

PSRR
∆VIO/∆VS

100

100

µV/V

80

80

dB

VOM+

3

3

V

Large Signal Voltage Gain (See Figures 6, 29)

Common Mode Rejection Ratio

CMRR

Common Mode Input Voltage Range (See Figure 8)

VICR

Power Supply Rejection Ratio

Maximum Output Voltage (See Figures 2, 8)

VOM-

0.13

0.13

V

Source

IOM+

10

10

mA

Sink

I

OM-

1

1

mA

Slew Rate (See Figure 31)

SR

7

7

V/µs

Gain-Bandwidth Product (See Figure 30)

fT

3.7

3.7

MHz

Supply Current (See Figure 32)

I+

1.6

1.6

mA

Device Dissipation

PD

8

8

mW

200

200

µA

Maximum Output Current:

Sink Current from Terminal 8 to Terminal 4 to Swing Output Low

4

FN957.10
July 11, 2005

CA3140, CA3140A
Block Diagram
2mA

4mA
7 V+

BIAS CIRCUIT
CURRENT SOURCES
AND REGULATOR
200µA

+

1.6mA

3

-

2µA

A≈
10,000

A ≈ 10

INPUT

200µA

2mA

A≈1

6 OUTPUT

2
C1
12pF

5
1
OFFSET
NULL

4 VSTROBE

8

Schematic Diagram
BIAS CIRCUIT

INPUT STAGE

SECOND STAGE

OUTPUT STAGE

DYNAMIC CURRENT SINK
7 V+

D1

D7

Q1

Q3

Q2

D8

R10
1K

Q4

Q5

Q6

Q20

R9
50Ω

Q19 R11
20Ω

Q7

R12
12K

R14
20K

Q21

Q17
R1
8K

R13
5K

R8

Q8

1K Q
18
6 OUTPUT
D2

D3

D4
D5

INVERTING
INPUT

2

NON-INVERTING
INPUT

3

-

Q9

+

Q10
C1

R2
500Ω

R3
500Ω

12pF
Q14

Q11

R4
500Ω

Q12

R5
500Ω

5

NOTE:

Q16
D6

R6
50Ω

1
OFFSET NULL

Q15

Q13

R7
30Ω

8

4

STROBE

V-

All resistance values are in ohms.

5

FN957.10
July 11, 2005

CA3140, CA3140A
Application Information
Circuit Description
As shown in the block diagram, the input terminals may be
operated down to 0.5V below the negative supply rail. Two
class A amplifier stages provide the voltage gain, and a
unique class AB amplifier stage provides the current gain
necessary to drive low-impedance loads.
A biasing circuit provides control of cascoded constant current
flow circuits in the first and second stages. The CA3140
includes an on chip phase compensating capacitor that is
sufficient for the unity gain voltage follower configuration.

Input Stage
The schematic diagram consists of a differential input stage
using PMOS field-effect transistors (Q9, Q10) working into a
mirror pair of bipolar transistors (Q11, Q12) functioning as load
resistors together with resistors R2 through R5. The mirror pair
transistors also function as a differential-to-single-ended
converter to provide base current drive to the second stage
bipolar transistor (Q13). Offset nulling, when desired, can be
effected with a 10kΩ potentiometer connected across
Terminals 1 and 5 and with its slider arm connected to Terminal
4. Cascode-connected bipolar transistors Q2, Q5 are the
constant current source for the input stage. The base biasing
circuit for the constant current source is described
subsequently. The small diodes D3, D4, D5 provide gate oxide
protection against high voltage transients, e.g., static electricity.

Second Stage
Most of the voltage gain in the CA3140 is provided by the
second amplifier stage, consisting of bipolar transistor Q13
and its cascode connected load resistance provided by
bipolar transistors Q3, Q4. On-chip phase compensation,
sufficient for a majority of the applications is provided by C1.
Additional Miller-Effect compensation (roll off) can be
accomplished, when desired, by simply connecting a small
capacitor between Terminals 1 and 8. Terminal 8 is also
used to strobe the output stage into quiescence. When
terminal 8 is tied to the negative supply rail (Terminal 4) by
mechanical or electrical means, the output Terminal 6
swings low, i.e., approximately to Terminal 4 potential.

Output Stage
The CA3140 Series circuits employ a broad band output stage
that can sink loads to the negative supply to complement the
capability of the PMOS input stage when operating near the
negative rail. Quiescent current in the emitter-follower cascade
circuit (Q17, Q18) is established by transistors (Q14, Q15)
whose base currents are “mirrored” to current flowing through
diode D2 in the bias circuit section. When the CA3140 is
operating such that output Terminal 6 is sourcing current,
transistor Q18 functions as an emitter-follower to source current
from the V+ bus (Terminal 7), via D7, R9, and R11. Under these
conditions, the collector potential of Q13 is sufficiently high to
permit the necessary flow of base current to emitter follower
Q17 which, in turn, drives Q18.
6

When the CA3140 is operating such that output Terminal 6 is
sinking current to the V- bus, transistor Q16 is the current
sinking element. Transistor Q16 is mirror connected to D6, R7,
with current fed by way of Q21, R12, and Q20. Transistor Q20, in
turn, is biased by current flow through R13, zener D8, and R14.
The dynamic current sink is controlled by voltage level sensing.
For purposes of explanation, it is assumed that output Terminal
6 is quiescently established at the potential midpoint between
the V+ and V- supply rails. When output current sinking mode
operation is required, the collector potential of transistor Q13 is
driven below its quiescent level, thereby causing Q17, Q18 to
decrease the output voltage at Terminal 6. Thus, the gate
terminal of PMOS transistor Q21 is displaced toward the V- bus,
thereby reducing the channel resistance of Q21. As a
consequence, there is an incremental increase in current flow
through Q20, R12, Q21, D6, R7, and the base of Q16. As a
result, Q16 sinks current from Terminal 6 in direct response to
the incremental change in output voltage caused by Q18. This
sink current flows regardless of load; any excess current is
internally supplied by the emitter-follower Q18. Short circuit
protection of the output circuit is provided by Q19, which is
driven into conduction by the high voltage drop developed
across R11 under output short circuit conditions. Under these
conditions, the collector of Q19 diverts current from Q4 so as to
reduce the base current drive from Q17, thereby limiting current
flow in Q18 to the short circuited load terminal.

Bias Circuit
Quiescent current in all stages (except the dynamic current
sink) of the CA3140 is dependent upon bias current flow in R1.
The function of the bias circuit is to establish and maintain
constant current flow through D1, Q6, Q8 and D2. D1 is a diode
connected transistor mirror connected in parallel with the base
emitter junctions of Q1, Q2, and Q3. D1 may be considered as a
current sampling diode that senses the emitter current of Q6
and automatically adjusts the base current of Q6 (via Q1) to
maintain a constant current through Q6, Q8, D2. The base
currents in Q2, Q3 are also determined by constant current flow
D1. Furthermore, current in diode connected transistor Q2
establishes the currents in transistors Q14 and Q15.

Typical Applications
Wide dynamic range of input and output characteristics with
the most desirable high input impedance characteristics is
achieved in the CA3140 by the use of an unique design based
upon the PMOS Bipolar process. Input common mode voltage
range and output swing capabilities are complementary,
allowing operation with the single supply down to 4V.
The wide dynamic range of these parameters also means
that this device is suitable for many single supply
applications, such as, for example, where one input is driven
below the potential of Terminal 4 and the phase sense of the
output signal must be maintained – a most important
consideration in comparator applications.

FN957.10
July 11, 2005

CA3140, CA3140A
Output Circuit Considerations

level shifting circuitry usually associated with the 741 series
of operational amplifiers.

Excellent interfacing with TTL circuitry is easily achieved with
a single 6.2V zener diode connected to Terminal 8 as shown
in Figure 1. This connection assures that the maximum
output signal swing will not go more positive than the zener
voltage minus two base-to-emitter voltage drops within the
CA3140. These voltages are independent of the operating
supply voltage.

Figure 4 shows some typical configurations. Note that a
series resistor, RL, is used in both cases to limit the drive
available to the driven device. Moreover, it is recommended
that a series diode and shunt diode be used at the thyristor
input to prevent large negative transient surges that can
appear at the gate of thyristors, from damaging the
integrated circuit.

V+
5V TO 36V
8

2

Offset Voltage Nulling

LOGIC
SUPPLY
5V

7
6.2V
6

CA3140

TYPICAL
TTL GATE

≈ 5V

3

The input offset voltage can be nulled by connecting a 10kΩ
potentiometer between Terminals 1 and 5 and returning its
wiper arm to terminal 4, see Figure 3A. This technique,
however, gives more adjustment range than required and
therefore, a considerable portion of the potentiometer
rotation is not fully utilized. Typical values of series resistors
(R) that may be placed at either end of the potentiometer,
see Figure 3B, to optimize its utilization range are given in
the Electrical Specifications table.

4

OUTPUT STAGE TRANSISTOR (Q15, Q16)
SATURATION VOLTAGE (mV)

FIGURE 1. ZENER CLAMPING DIODE CONNECTED TO
TERMINALS 8 AND 4 TO LIMIT CA3140 OUTPUT
SWING TO TTL LEVELS
1000

100

An alternate system is shown in Figure 3C. This circuit uses
only one additional resistor of approximately the value
shown in the table. For potentiometers, in which the
resistance does not drop to 0Ω at either end of rotation, a
value of resistance 10% lower than the values shown in the
table should be used.

SUPPLY VOLTAGE (V-) = 0V
TA = 25oC

SUPPLY VOLTAGE (V+) = +5V

+15V
+30V

Low Voltage Operation
Operation at total supply voltages as low as 4V is possible
with the CA3140. A current regulator based upon the PMOS
threshold voltage maintains reasonable constant operating
current and hence consistent performance down to these
lower voltages.

10

1
0.01

0.1
1.0
LOAD (SINKING) CURRENT (mA)

10

The low voltage limitation occurs when the upper extreme of the
input common mode voltage range extends down to the voltage
at Terminal 4. This limit is reached at a total supply voltage just
below 4V. The output voltage range also begins to extend down
to the negative supply rail, but is slightly higher than that of the
input. Figure 8 shows these characteristics and shows that with
2V dual supplies, the lower extreme of the input common mode
voltage range is below ground potential.

FIGURE 2. VOLTAGE ACROSS OUTPUT TRANSISTORS (Q15
AND Q16) vs LOAD CURRENT

Figure 2 shows output current sinking capabilities of the
CA3140 at various supply voltages. Output voltage swing to
the negative supply rail permits this device to operate both
power transistors and thyristors directly without the need for
V+
V+
2

2

V+

7
2

7
6

CA3140
CA3140

6

CA3140

6
3

3

7

4

4

3

5

5
R

1

R

1

10kΩ

10kΩ

4
5

1
10kΩ

R
V-

V-

FIGURE 3A. BASIC

FIGURE 3B. IMPROVED RESOLUTION

V-

FIGURE 3C. SIMPLER IMPROVED RESOLUTION

FIGURE 3. THREE OFFSET VOLTAGE NULLING METHODS

7

FN957.10
July 11, 2005

CA3140, CA3140A

RS

V+
LOAD
30V
NO LOAD

2

MT2

7

120VAC

+HV

7

LOAD
6

CA3140

RL

2

3
CA3140

4

6

MT1

RL

3
4

FIGURE 4. METHODS OF UTILIZING THE VCE(SAT) SINKING CURRENT CAPABILITY OF THE CA3140 SERIES

FOLLOWER
+15V
7
0.1µF

3

SIMULATED
LOAD

10kΩ
6

CA3140

2kΩ

100pF

2

4
0.1µF
-15V
2kΩ

LOAD RESISTANCE (RL) = 2kΩ
LOAD CAPACITANCE (CL) = 100pF
SUPPLY VOLTAGE: VS = ±15V
TA = 25oC

0.05µF

10

1mV

1mV

INVERTING
5kΩ

8
INPUT VOLTAGE (V)

6

10mV

10mV

+15V

4

7

2
0

CA3140

200Ω

-4

-8
-10
0.1

6
100pF

3

-6

1mV
10mV

2kΩ

4

1mV

0.1µF

4.99kΩ

10mV

1.0
SETTLING TIME (µs)

SIMULATED
LOAD

5kΩ

INVERTING

-2

0.1µF

2

FOLLOWER

5.11kΩ

-15V
SETTLING POINT

10
D1

D2

1N914

FIGURE 5A. WAVEFORM

1N914

FIGURE 5B. TEST CIRCUITS
FIGURE 5. SETTLING TIME vs INPUT VOLTAGE

Bandwidth and Slew Rate
For those cases where bandwidth reduction is desired, for
example, broadband noise reduction, an external capacitor
connected between Terminals 1 and 8 can reduce the open
loop -3dB bandwidth. The slew rate will, however, also be
proportionally reduced by using this additional capacitor.
Thus, a 20% reduction in bandwidth by this technique will
also reduce the slew rate by about 20%.
Figure 5 shows the typical settling time required to reach
1mV or 10mV of the final value for various levels of large
signal inputs for the voltage follower and inverting unity gain
amplifiers.
8

The exceptionally fast settling time characteristics are largely
due to the high combination of high gain and wide bandwidth
of the CA3140; as shown in Figure 6.

Input Circuit Considerations
As mentioned previously, the amplifier inputs can be driven
below the Terminal 4 potential, but a series current limiting
resistor is recommended to limit the maximum input terminal
current to less than 1mA to prevent damage to the input
protection circuitry.
Moreover, some current limiting resistance should be
provided between the inverting input and the output when

FN957.10
July 11, 2005

CA3140, CA3140A

The typical input current is on the order of 10pA when the
inputs are centered at nominal device dissipation. As the
output supplies load current, device dissipation will increase,
raising the chip temperature and resulting in increased input
current. Figure 7 shows typical input terminal current versus
ambient temperature for the CA3140.

-75

SUPPLY VOLTAGE: VS = ±15V
TA = 25oC
100

φOL

RL = 2kΩ,
CL = 0pF

-90
-105
-120
-135

80

-150

OPEN LOOP PHASE
(DEGREES)

OPEN LOOP VOLTAGE GAIN (dB)

It is well known that MOSFET devices can exhibit slight
changes in characteristics (for example, small changes in

60
RL = 2kΩ,
CL = 100pF

40

input offset voltage) due to the application of large
differential input voltages that are sustained over long
periods at elevated temperatures.
Both applied voltage and temperature accelerate these
changes. The process is reversible and offset voltage shifts of
the opposite polarity reverse the offset. Figure 9 shows the
typical offset voltage change as a function of various stress
voltages at the maximum rating of 125oC (for metal can); at
lower temperatures (metal can and plastic), for example, at
85oC, this change in voltage is considerably less. In typical
linear applications, where the differential voltage is small and
symmetrical, these incremental changes are of about the
same magnitude as those encountered in an operational
amplifier employing a bipolar transistor input stage.

10K

INPUT CURRENT (pA)

the CA3140 is used as a unity gain voltage follower. This
resistance prevents the possibility of extremely large input
signal transients from forcing a signal through the input
protection network and directly driving the internal constant
current source which could result in positive feedback via the
output terminal. A 3.9kΩ resistor is sufficient.

SUPPLY VOLTAGE: VS = ±15V

1K

100

10

20
0
101

102

103

104
105
106
FREQUENCY (Hz)

107

1
-60

108

RL = ∞
0
+VICR AT TA = 125oC
+VICR AT TA = 25oC
+VICR AT TA = -55oC

-0.5
-1.0

+VOUT AT TA = 125oC
+VOUT AT TA = 25oC
+VOUT AT TA = -55oC

-1.5
-2.0
-2.5
-3.0

0

5

10
15
SUPPLY VOLTAGE (V+, V-)

20

-20

0

20
40
60
80
TEMPERATURE (oC)

100

120

140

FIGURE 7. INPUT CURRENT vs TEMPERATURE

INPUT AND OUTPUT VOLTAGE EXCURSIONS
FROM TERMINAL 4 (V-)

INPUT AND OUTPUT VOLTAGE EXCURSIONS
FROM TERMINAL 7 (V+)

FIGURE 6. OPEN LOOP VOLTAGE GAIN AND PHASE vs
FREQUENCY

-40

25

1.5
-VICR AT TA = 125oC

1.0

-VICR AT TA = 25oC

0.5

-VOUT FOR
TA = -55oC to 125oC

0

-VICR AT TA = -55oC

-0.5
-1.0
-1.5

0

5

10
15
SUPPLY VOLTAGE (V+, V-)

20

25

FIGURE 8. OUTPUT VOLTAGE SWING CAPABILITY AND COMMON MODE INPUT VOLTAGE RANGE vs SUPPLY VOLTAGE

9

FN957.10
July 11, 2005

CA3140, CA3140A

OFFSET VOLTAGE SHIFT (mV)

7

TA = 125oC
FOR METAL CAN PACKAGES
DIFFERENTIAL DC VOLTAGE
(ACROSS TERMINALS 2 AND 3) = 2V
OUTPUT STAGE TOGGLED

6
5
4
3
2

DIFFERENTIAL DC VOLTAGE
(ACROSS TERMINALS 2 AND 3) = 0V
OUTPUT VOLTAGE = V+ / 2

1
0
0

500

1000 1500 2000 2500 3000 3500 4000 4500
TIME (HOURS)

FIGURE 9. TYPICAL INCREMENTAL OFFSET VOLTAGE
SHIFT vs OPERATING LIFE

Super Sweep Function Generator
A function generator having a wide tuning range is shown in
Figure 10. The 1,000,000/1 adjustment range is
accomplished by a single variable potentiometer or by an
auxiliary sweeping signal. The CA3140 functions as a noninverting readout amplifier of the triangular signal developed
across the integrating capacitor network connected to the
output of the CA3080A current source.
Buffered triangular output signals are then applied to a
second CA3080 functioning as a high speed hysteresis
switch. Output from the switch is returned directly back to the
input of the CA3080A current source, thereby, completing
the positive feedback loop
The triangular output level is determined by the four 1N914
level limiting diodes of the second CA3080 and the resistor
divider network connected to Terminal No. 2 (input) of the
CA3080. These diodes establish the input trip level to this
switching stage and, therefore, indirectly determine the
amplitude of the output triangle.
Compensation for propagation delays around the entire loop
is provided by one adjustment on the input of the CA3080.
This adjustment, which provides for a constant generator
amplitude output, is most easily made while the generator is
sweeping. High frequency ramp linearity is adjusted by the
single 7pF to 60pF capacitor in the output of the CA3080A.
It must be emphasized that only the CA3080A is
characterized for maximum output linearity in the current
generator function.

Meter Driver and Buffer Amplifier
Figure 11 shows the CA3140 connected as a meter driver
and buffer amplifier. Low driving impedance is required of
the CA3080A current source to assure smooth operation of
the Frequency Adjustment Control. This low-driving
impedance requirement is easily met by using a CA3140
connected as a voltage follower. Moreover, a meter may be

10

placed across the input to the CA3080A to give a logarithmic
analog indication of the function generator’s frequency.
Analog frequency readout is readily accomplished by the
means described above because the output current of the
CA3080A varies approximately one decade for each 60mV
change in the applied voltage, VABC (voltage between
Terminals 5 and 4 of the CA3080A of the function generator).
Therefore, six decades represent 360mV change in VABC .
Now, only the reference voltage must be established to set
the lower limit on the meter. The three remaining transistors
from the CA3086 Array used in the sweep generator are
used for this reference voltage. In addition, this reference
generator arrangement tends to track ambient temperature
variations, and thus compensates for the effects of the
normal negative temperature coefficient of the CA3080A
VABC terminal voltage.
Another output voltage from the reference generator is used
to insure temperature tracking of the lower end of the
Frequency Adjustment Potentiometer. A large series
resistance simulates a current source, assuring similar
temperature coefficients at both ends of the Frequency
Adjustment Control.
To calibrate this circuit, set the Frequency Adjustment
Potentiometer at its low end. Then adjust the Minimum
Frequency Calibration Control for the lowest frequency. To
establish the upper frequency limit, set the Frequency
Adjustment Potentiometer to its upper end and then adjust
the Maximum Frequency Calibration Control for the
maximum frequency. Because there is interaction among
these controls, repetition of the adjustment procedure may
be necessary. Two adjustments are used for the meter. The
meter sensitivity control sets the meter scale width of each
decade, while the meter position control adjusts the pointer
on the scale with negligible effect on the sensitivity
adjustment. Thus, the meter sensitivity adjustment control
calibrates the meter so that it deflects 1/6 of full scale for
each decade change in frequency.

Sine Wave Shaper
The circuit shown in Figure 12 uses a CA3140 as a voltage
follower in combination with diodes from the CA3019 Array
to convert the triangular signal from the function generator to
a sine-wave output signal having typically less than 2% THD.
The basic zero crossing slope is established by the 10kΩ
potentiometer connected between Terminals 2 and 6 of the
CA3140 and the 9.1kΩ resistor and 10kΩ potentiometer
from Terminal 2 to ground. Two break points are established
by diodes D1 through D4. Positive feedback via D5 and D6
establishes the zero slope at the maximum and minimum
levels of the sine wave. This technique is necessary because
the voltage follower configuration approaches unity gain
rather than the zero gain required to shape the sine wave at
the two extremes.

FN957.10
July 11, 2005

CA3140, CA3140A
CENTERING
-15V 10kΩ

7.5kΩ

+15V

360Ω
3

7

+

15kΩ

-

2

4
5

2MΩ

51
pF

7-60
pF

-15V
+15V

39kΩ

120Ω

-15V

+
CA3140

3

6

0.1
µF

-15V
2kΩ
FREQUENCY
ADJUSTMENT

10kΩ

62kΩ

10kΩ

5.1kΩ

EXTERNAL
OUTPUT

EXTERNAL
OUTPUT

7

-

2
11kΩ
11kΩ
10kΩ

4

HIGH
FREQ.
SHAPE

+15V

5

-

2

100kΩ
FROM BUFFER METER
DRIVER (OPTIONAL)

0.1
µF

7

6

CA3080A

360Ω

SYMMETRY
-15V

+15V

HIGH
FREQUENCY
LEVEL
910kΩ
7-60pF

6

CA3080
+
4

3

2.7kΩ
-15V

13kΩ

TO OUTPUT
AMPLIFIER

TO
SINE WAVE
SHAPER

1N914

OUTPUT
AMPLIFIER

+15V

THIS NETWORK IS USED WHEN THE
OPTIONAL BUFFER CIRCUIT IS NOT USED

FIGURE 10A. CIRCUIT

FREQUENCY
ADJUSTMENT

Top Trace: Output at junction of 2.7Ω and 51Ω resistors;
5V/Div., 500ms/Div.
Center Trace: External output of triangular function generator;
2V/Div., 500ms/Div.

+15V

METER DRIVER
AND BUFFER
AMPLIFIER

Bottom Trace: Output of “Log” generator; 10V/Div., 500ms/Div.
FIGURE 10B. FIGURE FUNCTION GENERATOR SWEEPING

POWER
SUPPLY ±15V

M

-15V

FUNCTION
GENERATOR
WIDEBAND
LINE DRIVER

SINE WAVE
SHAPER

51Ω

SWEEP
GENERATOR

FINE
RATE

GATE DC LEVEL
SWEEP ADJUST
OFF INT.

COARSE
RATE

1V/Div., 1s/Div.

EXT.

EXTERNAL
INPUT

SWEEP
LENGTH

Three tone test signals, highest frequency ≥0.5MHz. Note the slight
asymmetry at the three second/cycle signal. This asymmetry is due to
slightly different positive and negative integration from the CA3080A
and from the PC board and component leakages at the 100pA level.
FIGURE 10C. FUNCTION GENERATOR WITH FIXED
FREQUENCIES

V-

V-

FIGURE 10D. INTERCONNECTIONS

FIGURE 10. FUNCTION GENERATOR

11

FN957.10
July 11, 2005

CA3140, CA3140A

500kΩ
FREQUENCY
ADJUSTMENT
10kΩ

FREQUENCY
CALIBRATION
MAXIMUM
620kΩ
7
51kΩ
3
+
6

CA3140

SWEEP IN
3MΩ

-

2

4.7kΩ
4
+15V

2kΩ

12kΩ
FREQUENCY 2.4kΩ
CALIBRATION
MINIMUM
2.5
kΩ

0.1µF
3
5.1kΩ

510Ω

6

5

9

3.6kΩ 13

8
D6

D3

12

METER
POSITION
ADJUSTMENT

D4

9.1kΩ

R1
10kΩ

14

2kΩ

7

10kΩ
EXTERNAL
OUTPUT

D1

-15V

6

TO
WIDEBAND
OUTPUT
AMPLIFIER

1MΩ

100
kΩ

10

6
SUBSTRATE
OF CA3019

7
-15V
R3 10kΩ

+15V

9
8

4

0.1µF

1kΩ
200µA
M METER

510Ω

-

620Ω

11

5.6kΩ
7.5kΩ

7

+

CA3140
2

METER
SENSITIVITY
ADJUSTMENT

0.1µF

-15V

+15V

TO CA3080A
OF FUNCTION CA3080A
GENERATOR
(FIGURE 10)
4
5

2
430Ω

D2
1

R2
1kΩ

3
4
D
CA3019 5
DIODE ARRAY

3/ OF CA3086
5

-15V

FIGURE 11. METER DRIVER AND BUFFER AMPLIFIER

FIGURE 12. SINE WAVE SHAPER

750kΩ
“LOG”
SAWTOOTH 18MΩ
1N914

100kΩ
100kΩ FINE
RATE

1MΩ
22MΩ
SAWTOOTH
SYMMETRY

1N914
0.47µF
0.047µF

8.2kΩ

+15V SAWTOOTH AND
RAMP LOW LEVEL
SET (-14.5V)

COARSE
RATE

4700pF

50kΩ
75kΩ

470pF

7

+15V
0.1
µF

2

-

3

CA3140
+
4

51kΩ

SAWTOOTH
“LOG”+15V

6

50kΩ
LOG
RATE
ADJUST

-15V
43kΩ

10kΩ
10kΩ

7

-

3

CA3140
+
4

100kΩ
TO OUTPUT 2
AMPLIFIER

30kΩ

0.1
µF

+15V
36kΩ

TRIANGLE

6

10kΩ

GATE
PULSE
OUTPUT

-15V

EXTERNAL OUTPUT

TO FUNCTION GENERATOR “SWEEP IN”
SWEEP WIDTH

-15V
3

6

CA3140

2
LOGVIO

+15V

7

+

5

1

51kΩ

4

6.8kΩ

91kΩ

10kΩ
TRIANGLE

25kΩ
3.9Ω
-15V

5

1
4

2

100Ω
390Ω

TRANSISTORS
FROM CA3086
ARRAY

SAWTOOTH
“LOG”

3

FIGURE 13. SWEEPING GENERATOR

12

FN957.10
July 11, 2005

CA3140, CA3140A
This circuit can be adjusted most easily with a distortion
analyzer, but a good first approximation can be made by
comparing the output signal with that of a sine wave
generator. The initial slope is adjusted with the potentiometer
R1, followed by an adjustment of R2. The final slope is
established by adjusting R3, thereby adding additional
segments that are contributed by these diodes. Because
there is some interaction among these controls, repetition of
the adjustment procedure may be necessary.

REFERENCE
VOLTAGE

VOLTAGE
ADJUSTMENT
3

+

7

CA3140

INPUT
2

6

REGULATED
OUTPUT

4

Sweeping Generator
Figure 13 shows a sweeping generator. Three CA3140s are
used in this circuit. One CA3140 is used as an integrator, a
second device is used as a hysteresis switch that determines
the starting and stopping points of the sweep. A third
CA3140 is used as a logarithmic shaping network for the log
function. Rates and slopes, as well as sawtooth, triangle,
and logarithmic sweeps are generated by this circuit.
Wideband Output Amplifier
Figure 14 shows a high slew rate, wideband amplifier
suitable for use as a 50Ω transmission line driver. This
circuit, when used in conjunction with the function generator
and sine wave shaper circuits shown in Figures 10 and 12
provides 18VP-P output open circuited, or 9VP-P output
when terminated in 50Ω. The slew rate required of this
amplifier is 28V/µs (18VP-P x π x 0.5MHz).
+15V

+

SIGNAL
LEVEL
ADJUSTMENT
2.5kΩ

3

7

+

2

-

4

+

+15V
3kΩ
-15V
200Ω

2.4pF
2pF

1.8kΩ

2N3053

1N914

2.7Ω

1N914

2.7Ω

51Ω

OUT

2W

8

1
OUTPUT
DC LEVEL
ADJUSTMENT

2.2
kΩ

6

CA3140
200Ω

50µF
25V

50µF
25V

2.2
kΩ

2N4037
-15V

NOMINAL BANDWIDTH = 10MHz
tr = 35ns

FIGURE 14. WIDEBAND OUTPUT AMPLIFIER

Power Supplies
High input impedance, common mode capability down to the
negative supply and high output drive current capability are
key factors in the design of wide range output voltage
supplies that use a single input voltage to provide a
regulated output voltage that can be adjusted from
essentially 0V to 24V.
Unlike many regulator systems using comparators having a
bipolar transistor input stage, a high impedance reference
voltage divider from a single supply can be used in
connection with the CA3140 (see Figure 15).

13

FIGURE 15. BASIC SINGLE SUPPLY VOLTAGE REGULATOR
SHOWING VOLTAGE FOLLOWER CONFIGURATION

Essentially, the regulators, shown in Figures 16 and 17, are
connected as non inverting power operational amplifiers with a
gain of 3.2. An 8V reference input yields a maximum output
voltage slightly greater than 25V. As a voltage follower, when
the reference input goes to 0V the output will be 0V. Because
the offset voltage is also multiplied by the 3.2 gain factor, a
potentiometer is needed to null the offset voltage.
Series pass transistors with high ICBO levels will also
prevent the output voltage from reaching zero because there
is a finite voltage drop (VCESAT) across the output of the
CA3140 (see Figure 2). This saturation voltage level may
indeed set the lowest voltage obtainable.
The high impedance presented by Terminal 8 is
advantageous in effecting current limiting. Thus, only a small
signal transistor is required for the current-limit sensing
amplifier. Resistive decoupling is provided for this transistor
to minimize damage to it or the CA3140 in the event of
unusual input or output transients on the supply rail.
Figures 16 and 17, show circuits in which a D2201 high speed
diode is used for the current sensor. This diode was chosen
for its slightly higher forward voltage drop characteristic, thus
giving greater sensitivity. It must be emphasized that heat
sinking of this diode is essential to minimize variation of the
current trip point due to internal heating of the diode. That is,
1A at 1V forward drop represents one watt which can result in
significant regenerative changes in the current trip point as the
diode temperature rises. Placing the small signal reference
amplifier in the proximity of the current sensing diode also
helps minimize the variability in the trip level due to the
negative temperature coefficient of the diode. In spite of those
limitations, the current limiting point can easily be adjusted
over the range from 10mA to 1A with a single adjustment
potentiometer. If the temperature stability of the current
limiting system is a serious consideration, the more usual
current sampling resistor type of circuitry should be employed.
A power Darlington transistor (in a metal can with heatsink),
is used as the series pass element for the conventional
current limiting system, Figure 16, because high power
Darlington dissipation will be encountered at low output
voltage and high currents.

FN957.10
July 11, 2005

CA3140, CA3140A
A small heat sink VERSAWATT transistor is used as the
series pass element in the fold back current system, Figure
17, since dissipation levels will only approach 10W. In this
system, the D2201 diode is used for current sampling.
Foldback is provided by the 3kΩ and 100kΩ divider network
connected to the base of the current sensing transistor.
Both regulators provide better than 0.02% load regulation.
Because there is constant loop gain at all voltage settings, the

+30V

3

2N6385
CURRENT
POWER DARLINGTON LIMITING
ADJUST
D2201
2

OUTPUT
0.1 ⇒ 24V
AT 1A

regulation also remains constant. Line regulation is 0.1% per
volt. Hum and noise voltage is less than 200µV as read with a
meter having a 10MHz bandwidth.
Figure 18A shows the turn ON and turn OFF characteristics
of both regulators. The slow turn on rise is due to the slow
rate of rise of the reference voltage. Figure 18B shows the
transient response of the regulator with the switching of a
20Ω load at 20V output.

+30V

1kΩ 200Ω

75Ω

1kΩ

1kΩ

1

1kΩ

100Ω
8

56pF

8

2.7kΩ 10µF

5

-

1kΩ

2.2kΩ

+

2.7kΩ 10µF

4

-

10 11

1 2

9

3

8 7

5

6

4

5µF 50kΩ
14

180kΩ

5

-

1kΩ

CA3140

6
82kΩ

1

100kΩ

82kΩ

3
4

INPUT

INPUT
+

56pF
2

3

1

100kΩ

1kΩ

7

180kΩ

2
CA3140

3kΩ
2N2102

3

1kΩ

7

+

100kΩ

100kΩ

2N2102
1

1

2

3kΩ

6

OUTPUT ⇒ 0V TO 25V
25V AT 1A
“FOLDS BACK”
TO 40mA

“FOLDBACK” CURRENT
LIMITER
2N5294
D2201
2
3

VOLTAGE
ADJUST
100kΩ

+

-

250µF

12
0.01µF

+

2.2kΩ

-

10 11

1 2

9

3

8 7

5

6

4

5µF 50kΩ
14

VOLTAGE
ADJUST
100kΩ

+

-

250µF

12
0.01µF
13

13
CA3086

CA3086
1kΩ
1kΩ

62kΩ

62kΩ
HUM AND NOISE OUTPUT <200µVRMS
(MEASUREMENT BANDWIDTH ~10MHz)
LINE REGULATION 0.1%/V

LOAD REGULATION
(NO LOAD TO FULL LOAD)
<0.02%

FIGURE 16. REGULATED POWER SUPPLY

5V/Div., 1s/Div.

FIGURE 18A. SUPPLY TURN-ON AND TURNOFF
CHARACTERISTICS

HUM AND NOISE OUTPUT <200µVRMS
(MEASUREMENT BANDWIDTH ~10MHz)
LINE REGULATION 0.1%/V

LOAD REGULATION
(NO LOAD TO FULL LOAD)
<0.02%

FIGURE 17. REGULATED POWER SUPPLY WITH “FOLDBACK”
CURRENT LIMITING

Top Trace: Output Voltage;
200mV/Div., 5µs/Div.
Bottom Trace: Collector of load switching transistor, load = 1A;
5V/Div., 5µs/Div.
FIGURE 18B. TRANSIENT RESPONSE

FIGURE 18. WAVEFORMS OF DYNAMIC CHARACTERISTICS OF POWER SUPPLY CURRENTS SHOWN IN FIGURES 16 AND 17

14

FN957.10
July 11, 2005

CA3140, CA3140A
Bass treble boost and cut are ±15dB at 100Hz and 10kHz,
respectively. Full peak-to-peak output is available up to at
least 20kHz due to the high slew rate of the CA3140. The
amplifier gain is 3dB down from its “flat” position at 70kHz.

Tone Control Circuits
High slew rate, wide bandwidth, high output voltage
capability and high input impedance are all characteristics
required of tone control amplifiers. Two tone control circuits
that exploit these characteristics of the CA3140 are shown in
Figures 19 and 20.

Figure 19 shows another tone control circuit with similar
boost and cut specifications. The wideband gain of this
circuit is equal to the ultimate boost or cut plus one, which in
this case is a gain of eleven. For 20dB boost and cut, the
input loading of this circuit is essentially equal to the value of
the resistance from Terminal No. 3 to ground. A detailed
analysis of this circuit is given in “An IC Operational
Transconductance Amplifier (OTA) With Power Capability” by
L. Kaplan and H. Wittlinger, IEEE Transactions on Broadcast
and Television Receivers, Vol. BTR-18, No. 3, August, 1972.

The first circuit, shown in Figure 20, is the Baxandall tone
control circuit which provides unity gain at midband and
uses standard linear potentiometers. The high input
impedance of the CA3140 makes possible the use of lowcost, low-value, small size capacitors, as well as reduced
load of the driving stage.

FOR SINGLE SUPPLY

NOTES:

+30V
2.2MΩ

5. 20dB Flat Position Gain.
7

0.005µF
5.1
MΩ

3

+
CA3140

2

-

6. ±15dB Bass and Treble Boost and Cut
at 100Hz and 10kHz, respectively.

0.1µF

7. 25VP-P output at 20kHz.
8. -3dB at 24kHz from 1kHz reference.

6

4
BOOST

2.2MΩ

0.1
µF

0.012µF

TREBLE
CUT
200kΩ
(LINEAR) 0.001µF

18kΩ

100
pF

FOR DUAL SUPPLIES
+15V

3

7
+
CA3140

2

-

0.005µF

100pF

5.1MΩ

4
0.022µF
2µF
- +

0.0022µF

0.1µF
6

0.1µF

-15V

10kΩ

1MΩ
100kΩ
CCW (LOG)
BOOST
BASS
CUT
TONE CONTROL NETWORK

TONE CONTROL NETWORK

FIGURE 19. TONE CONTROL CIRCUIT USING CA3130 SERIES (20dB MIDBAND GAIN)
FOR SINGLE SUPPLY
BOOST
0.047µF

BASS
CUT
(LINEAR)
240kΩ
240kΩ
5MΩ

FOR DUAL SUPPLIES
2.2MΩ

750
pF

+32V

750
pF

+15V
7
3

2.2MΩ

0.1
µF

2.2
MΩ 2

+
CA3140

51kΩ

5MΩ
51kΩ
(LINEAR)
BOOST TREBLE
CUT
TONE CONTROL NETWORK

6
0.047µF

4

20pF

0.1
µF

TONE CONTROL
NETWORK

3

7
+
CA3140

2

-

ΝΟΤΕΣ:
9. ±15dB Bass and Treble Boost and Cut at 100Hz and 10kHz, Respectively.
10. 25VP-P Output at 20kHz.
11. -3dB at 70kHz from 1kHz Reference.
12. 0dB Flat Position Gain.

4

0.1µF
6

0.1µF

-15V

FIGURE 20. BAXANDALL TONE CONTROL CIRCUIT USING CA3140 SERIES

15

FN957.10
July 11, 2005

CA3140, CA3140A
Wien Bridge Oscillator
Another application of the CA3140 that makes excellent use
of its high input impedance, high slew rate, and high voltage
qualities is the Wien Bridge sine wave oscillator. A basic Wien
Bridge oscillator is shown in Figure 21. When R1 = R2 = R
and C1 = C2 = C, the frequency equation reduces to the
familiar f = 1/(2πRC) and the gain required for oscillation,
AOSC is equal to 3. Note that if C2 is increased by a factor of
four and R2 is reduced by a factor of four, the gain required
for oscillation becomes 1.5, thus permitting a potentially
higher operating frequency closer to the gain bandwidth
product of the CA3140.
C2

R2

NOTES:

+
OUTPUT

RF
C1

R1

RF
A CL = 1 + ------RS

RS

1000pF
3
C1 2
1000
pF

R1

FIGURE 21. BASIC WIEN BRIDGE OSCILLATOR CIRCUIT
USING AN OPERATIONAL AMPLIFIER

Oscillator stabilization takes on many forms. It must be
precisely set, otherwise the amplitude will either diminish or
reach some form of limiting with high levels of distortion. The
element, RS, is commonly replaced with some variable
resistance element. Thus, through some control means, the
value of RS is adjusted to maintain constant oscillator output.
A FET channel resistance, a thermistor, a lamp bulb, or other
device whose resistance increases as the output amplitude
is increased are a few of the elements often utilized.
Figure 22 shows another means of stabilizing the oscillator
with a zener diode shunting the feedback resistor (RF of
Figure 21). As the output signal amplitude increases, the
zener diode impedance decreases resulting in more
feedback with consequent reduction in gain; thus stabilizing
the amplitude of the output signal. Furthermore, this
combination of a monolithic zener diode and bridge rectifier
circuit tends to provide a zero temperature coefficient for this
regulating system. Because this bridge rectifier system has
no time constant, i.e., thermal time constant for the lamp
bulb, and RC time constant for filters often used in detector
networks, there is no lower frequency limit. For example, with
1µF polycarbonate capacitors and 22MΩ for the frequency
determining network, the operating frequency is 0.007Hz.
As the frequency is increased, the output amplitude must be
reduced to prevent the output signal from becoming slewrate limited. An output frequency of 180kHz will reach a slew
rate of approximately 9V/µs when its amplitude is 16VP-P.

7
+
CA3140

4

0.1µF

CA3109
DIODE
ARRAY

6
SUBSTRATE
OF CA3019

8

9

1
2

6

0.1µF

3

7
0.1µF

-15V

7.5kΩ

5

4

R 1 = R2 = R

50Hz, R =
100Hz, R =
1kHz, R =
10kHz, R =
30kHz, R =

1
f = ------------------------------------------2π R 1 C 1 R 2 C 2
C
R
A OSC = 1 + ------1- + ------2C2 R1

+15V

R2
C2

OUTPUT
19VP-P TO 22VP-P
THD <0.3%

3.3MΩ
1.6MΩ
160MΩ
16MΩ
5.1MΩ

3.6kΩ
500Ω

FIGURE 22. WIEN BRIDGE OSCILLATOR CIRCUIT USING
CA3140

Simple Sample-and-Hold System
Figure 23 shows a very simple sample-and-hold system
using the CA3140 as the readout amplifier for the storage
capacitor. The CA3080A serves as both input buffer amplifier
and low feed-through transmission switch (see Note 13).
System offset nulling is accomplished with the CA3140 via
its offset nulling terminals. A typical simulated load of 2kΩ
and 30pF is shown in the schematic.
0

30kΩ

SAMPLE

STROBE
-15

1N914

HOLD

+15V
1N914
INPUT

+15V
5

2kΩ

+

3

CA3080A

-

2

0.1µF

7
6

4

0.1µF
2kΩ

3.5kΩ

7
3

+
CA3140

2

-

6
0.1
µF

4

5

1

100kΩ

-15V

-15V
200pF

2kΩ

C1

200pF

2kΩ

400Ω

0.1µF
30pF
SIMULATED LOAD
NOT REQUIRED

FIGURE 23. SAMPLE AND HOLD CIRCUIT

In this circuit, the storage compensation capacitance (C1) is
only 200pF. Larger value capacitors provide longer “hold”
periods but with slower slew rates. The slew rate is:
dv
I
------ = ---- = 0.5mA ⁄ 200pF = 2.5V ⁄ µs
dt
C
NOTE:
13. AN6668 “Applications of the CA3080 and CA 3080A High
Performance Operational Transconductance Amplifiers”.

16

FN957.10
July 11, 2005

CA3140, CA3140A
Pulse “droop” during the hold interval is 170pA/200pF which is
0.85µV/µs; (i.e., 170pA/200pF). In this case, 170pA represents
the typical leakage current of the CA3080A when strobed off. If
C1 were increased to 2000pF, the “hold-droop” rate will
decrease to 0.085µV/µs, but the slew rate would decrease to
0.25V/µs. The parallel diode network connected between
Terminal 3 of the CA3080A and Terminal 6 of the CA3140
prevents large input signal feedthrough across the input
terminals of the CA3080A to the 200pF storage capacitor when
the CA3080A is strobed off. Figure 24 shows dynamic
characteristic waveforms of this sample-and-hold system.

Current Amplifier
The low input terminal current needed to drive the CA3140
makes it ideal for use in current amplifier applications such
as the one shown in Figure 25 (see Note 14). In this circuit,
low current is supplied at the input potential as the power
supply to load resistor RL. This load current is increased by
the multiplication factor R2/R1, when the load current is
monitored by the power supply meter M. Thus, if the load
current is 100nA, with values shown, the load current
presented to the supply will be 100µA; a much easier current
to measure in many systems.
R1
10kΩ
+15V
IL x

R2
R1

0.1µF
7
+
CA3140

3
M

-

2
POWER
SUPPLY

5

4

1

6
0.1µF

R2
10MΩ

IL
RL

100kΩ

Top Trace: Output; 50mV/Div., 200ns/Div.
Bottom Trace: Input; 50mV/Div., 200ns/Div.

4.3kΩ
-15V

FIGURE 25. BASIC CURRENT AMPLIFIER FOR LOW CURRENT
MEASUREMENT SYSTEMS

Note that the input and output voltages are transferred at the
same potential and only the output current is multiplied by
the scale factor.

Top Trace: Output Signal; 5V/Div, 2µs/Div.
Center Trace: Difference of Input and Output Signals through
Tektronix Amplifier 7A13; 5mV/Div., 2µs/Div.
Bottom Trace: Input Signal; 5V/Div., 2µs/Div.
LARGE SIGNAL RESPONSE AND SETTLING TIME

SAMPLING RESPONSE
Top Trace: Output; 100mV/Div., 500ns/Div.
Bottom Trace: Input; 20V/Div., 500ns/Div.
FIGURE 24. SAMPLE AND HOLD SYSTEM DYNAMIC
CHARACTERISTICS WAVEFORMS

17

The dotted components show a method of decoupling the
circuit from the effects of high output load capacitance and
the potential oscillation in this situation. Essentially, the
necessary high frequency feedback is provided by the
capacitor with the dotted series resistor providing load
decoupling.
Full Wave Rectifier
Figure 26 shows a single supply, absolute value, ideal fullwave rectifier with associated waveforms. During positive
excursions, the input signal is fed through the feedback
network directly to the output. Simultaneously, the positive
excursion of the input signal also drives the output terminal
(No. 6) of the inverting amplifier in a negative going
excursion such that the 1N914 diode effectively disconnects
the amplifier from the signal path. During a negative going
excursion of the input signal, the CA3140 functions as a
normal inverting amplifier with a gain equal to -R2/R1. When
the equality of the two equations shown in Figure 26 is
satisfied, the full wave output is symmetrical.
NOTE:
14. “Operational Amplifiers Design and Applications”, J. G. Graeme,
McGraw-Hill Book Company, page 308, “Negative Immittance
Converter Circuits”.

FN957.10
July 11, 2005

CA3140, CA3140A
+15V

R2
5kΩ

+15V
0.1µF
0.1µF

R1
10kΩ

+
8

3

5

1

6
4

2

1N914
10kΩ
R3

100kΩ
OFFSET
ADJUST

PEAK
ADJUST
10kΩ

6

-

100pF

4

2kΩ

0.1µF
-15V
2kΩ

R
R3
GAIN = ------2- = X = ---------------------------R1
R1 R2 + R3

SIMULATED
LOAD

+
CA3140

CA3140
3

INPUT

7

-

2

7

10kΩ

BW (-3dB) = 4.5MHz
SR = 9V/µs

0.05µF

FIGURE 28A. TEST CIRCUIT

2

X+X
R 3 =  ----------------- R 1
 1–X 
R
5kΩ
FOR X = 0.5 --------------- = ------210kΩ
R1
0.75
R 3 = 10kΩ  ----------- = 15kΩ
 0.5 

20VP-P Input BW (-3dB) = 290kHz, DC Output (Avg) = 3.2V

OUTPUT
0

Top Trace: Output; 50mV/Div., 200ns/Div.
Bottom Trace: Input; 50mV/Div., 200ns/Div.

INPUT
0

FIGURE 28B. SMALL SIGNAL RESPONSE

FIGURE 26. SINGLE SUPPLY, ABSOLUTE VALUE, IDEAL
FULL WAVE RECTIFIER WITH ASSOCIATED
WAVEFORMS

+15V
7

RS
3
1MΩ

0.01µF

+
6

CA3140
2

-

NOISE VOLTAGE
OUTPUT

4
0.01µF

30.1kΩ

(Measurement made with Tektronix 7A13 differential amplifier.)
Top Trace: Output Signal; 5V/Div., 5µs/Div.

-15V

Center Trace: Difference Signal; 5mV/Div., 5µs/Div.
BW (-3dB) = 140kHz
TOTAL NOISE VOLTAGE
(REFERRED TO INPUT) = 48µV (TYP)

1kΩ

FIGURE 27. TEST CIRCUIT AMPLIFIER (30dB GAIN) USED FOR
WIDEBAND NOISE MEASUREMENT

18

Bottom Trace: Input Signal; 5V/Div., 5µs/Div.
FIGURE 28C. INPUT-OUTPUT DIFFERENCE SIGNAL SHOWING
SETTLING TIME
FIGURE 28. SPLIT SUPPLY VOLTAGE FOLLOWER TEST
CIRCUIT AND ASSOCIATED WAVEFORMS

FN957.10
July 11, 2005

CA3140, CA3140A
Typical Performance Curves
20
GAIN BANDWIDTH PRODUCT (MHz)

OPEN-LOOP VOLTAGE GAIN (dB)

RL = 2kΩ

TA = -55oC
25oC

125

125oC

100
75
50
25

RL = 2kΩ
CL = 100pF
10

TA = -55oC

1

0
0

5

10

15

20

0

25

5

SUPPLY VOLTAGE (V)

QUIESCENT SUPPLY CURRENT (mA)

125oC
TA = -55oC

SLEW RATE (V/µs)

15
10
5
0
5

10
15
SUPPLY VOLTAGE (V)

20

25

25

COMMON-MODE REJECTION RATIO (dB)

25

20

15

10

5

1M

FREQUENCY (Hz)

FIGURE 33. MAXIMUM OUTPUT VOLTAGE SWING vs
FREQUENCY

19

6

TA = -55oC

25oC

5

125oC

4
3
2
1
0

0

5

10

15

25

20

FIGURE 32. QUIESCENT SUPPLY CURRENT vs SUPPLY
VOLTAGE AND TEMPERATURE

SUPPLY VOLTAGE: VS = ±15V
TA = 25oC

100K

7

SUPPLY VOLTAGE (V)

FIGURE 31. SLEW RATE vs SUPPLY VOLTAGE AND
TEMPERATURE

0
10K

20

RL = ∞

25oC

0

15

FIGURE 30. GAIN BANDWIDTH PRODUCT vs SUPPLY
VOLTAGE AND TEMPERATURE

RL = 2kΩ
CL = 100pF

20

10

SUPPLY VOLTAGE (V)

FIGURE 29. OPEN-LOOP VOLTAGE GAIN vs SUPPLY
VOLTAGE AND TEMPERATURE

OUTPUT SWING (VP-P)

25oC
125oC

4M

120 SUPPLY VOLTAGE: VS = ±15V
TA = 25oC
100
80
60
40
20
0
101

102

103
104
105
FREQUENCY (Hz)

106

107

FIGURE 34. COMMON MODE REJECTION RATIO vs FREQUENCY

FN957.10
July 11, 2005

CA3140, CA3140A
Typical Performance Curves

SUPPLY VOLTAGE: VS = ±15V
TA = 25oC

SUPPLY VOLTAGE: VS = ±15V
TA = 25oC
POWER SUPPLY REJECTION RATIO (dB)

EQUIVALENT INPUT NOISE VOLTAGE (nV/√Hz)

1000

(Continued)

100

10

1
1

101

102
103
FREQUENCY (Hz)

104

FIGURE 35. EQUIVALENT INPUT NOISE VOLTAGE vs
FREQUENCY

20

105

100
+PSRR

80

60

40

-PSRR

20
POWER SUPPLY REJECTION RATIO
(PSRR) = ∆VIO/∆VS
0
101

102

103
104
105
FREQUENCY (Hz)

106

107

FIGURE 36. POWER SUPPLY REJECTION RATIO vs FREQUENCY

FN957.10
July 11, 2005

CA3140, CA3140A
Metallization Mask Layout

0
61

10

20

30

40

50

60

65

60

50

40

58-66
(1.473-1.676)

30

20

10

0
4-10
(0.102-0.254)
62-70
(1.575-1.778)

Dimensions in parenthesis are in millimeters and are derived
from the basic inch dimensions as indicated. Grid graduations
are in mils (10-3 inch).
The photographs and dimensions represent a chip when it is
part of the wafer. When the wafer is cut into chips, the cleavage
angles are 57o instead of 90ο with respect to the face of the
chip. Therefore, the isolated chip is actually 7 mils (0.17mm)
larger in both dimensions.

21

FN957.10
July 11, 2005

CA3140, CA3140A
Dual-In-Line Plastic Packages (PDIP)
E8.3 (JEDEC MS-001-BA ISSUE D)

N

8 LEAD DUAL-IN-LINE PLASTIC PACKAGE

E1
INDEX
AREA

1 2 3

INCHES

N/2
-B-

-AD

E

BASE
PLANE

-C-

A2

SEATING
PLANE

A
L

D1

e

B1

D1

A1

eC

B
0.010 (0.25) M

C A B S

MILLIMETERS

SYMBOL

MIN

MAX

MIN

MAX

NOTES

A

-

0.210

-

5.33

4

A1

0.015

-

0.39

-

4

A2

0.115

0.195

2.93

4.95

-

B

0.014

0.022

0.356

0.558

-

C
L

B1

0.045

0.070

1.15

1.77

8, 10

eA

C

0.008

0.014

0.204

C

D

0.355

0.400

9.01

eB

NOTES:
1. Controlling Dimensions: INCH. In case of conflict between
English and Metric dimensions, the inch dimensions control.

0.005

-

0.13

-

5

E

0.300

0.325

7.62

8.25

6

E1

0.240

0.280

6.10

7.11

5

e

0.100 BSC

eA

0.300 BSC

3. Symbols are defined in the “MO Series Symbol List” in Section
2.2 of Publication No. 95.

eB

-

L

0.115

5. D, D1, and E1 dimensions do not include mold flash or protrusions. Mold flash or protrusions shall not exceed 0.010 inch
(0.25mm).
6. E and eA are measured with the leads constrained to be perpendicular to datum -C- .

5

D1

2. Dimensioning and tolerancing per ANSI Y14.5M-1982.

4. Dimensions A, A1 and L are measured with the package seated
in JEDEC seating plane gauge GS-3.

0.355
10.16

N

8

2.54 BSC
7.62 BSC

0.430

-

0.150

2.93

10.92
3.81
8

6
7
4
9
Rev. 0 12/93

7. eB and eC are measured at the lead tips with the leads unconstrained. eC must be zero or greater.
8. B1 maximum dimensions do not include dambar protrusions.
Dambar protrusions shall not exceed 0.010 inch (0.25mm).
9. N is the maximum number of terminal positions.
10. Corner leads (1, N, N/2 and N/2 + 1) for E8.3, E16.3, E18.3,
E28.3, E42.6 will have a B1 dimension of 0.030 - 0.045 inch
(0.76 - 1.14mm).

22

FN957.10
July 11, 2005

CA3140, CA3140A
Small Outline Plastic Packages (SOIC)
M8.15 (JEDEC MS-012-AA ISSUE C)

N
INDEX
AREA

0.25(0.010) M

H

8 LEAD NARROW BODY SMALL OUTLINE PLASTIC
PACKAGE

B M

E

INCHES
-B-

1

2

SYMBOL

3

L
SEATING PLANE

-A-

h x 45o

A

D
-C-

µα

e

A1

B
0.25(0.010) M

C

C A M

B S

1. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of
Publication Number 95.

MILLIMETERS
MIN

MAX

NOTES

A

0.0532

0.0688

1.35

1.75

-

0.0040

0.0098

0.10

0.25

-

B

0.013

0.020

0.33

0.51

9

C

0.0075

0.0098

0.19

0.25

-

D

0.1890

0.1968

4.80

5.00

3

E

0.1497

0.1574

3.80

4.00

4

0.050 BSC

1.27 BSC

-

H

0.2284

0.2440

5.80

6.20

-

h

0.0099

0.0196

0.25

0.50

5

L

0.016

0.050

0.40

1.27

6

8o

0o

N

NOTES:

MAX

A1

e

0.10(0.004)

MIN

α

8
0o

8

7
8o

Rev. 0 12/93

2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Dimension “D” does not include mold flash, protrusions or gate burrs.
Mold flash, protrusion and gate burrs shall not exceed 0.15mm (0.006
inch) per side.
4. Dimension “E” does not include interlead flash or protrusions. Interlead flash and protrusions shall not exceed 0.25mm (0.010 inch) per
side.
5. The chamfer on the body is optional. If it is not present, a visual index
feature must be located within the crosshatched area.
6. “L” is the length of terminal for soldering to a substrate.
7. “N” is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. The lead width “B”, as measured 0.36mm (0.014 inch) or greater
above the seating plane, shall not exceed a maximum value of
0.61mm (0.024 inch).
10. Controlling dimension: MILLIMETER. Converted inch dimensions
are not necessarily exact.

All Intersil U.S. products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at www.intersil.com/design/quality
Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
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.

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23

FN957.10
July 11, 2005