Maximum Junction Temperature (Plastic Package) . . . . . . . .150
o
C
Maximum Storage Temperature Range . . . . . . . . . . -65
o
C to 150
o
C
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300
o
C
(SOIC - Lead Tips Only)
*Pb-free PDIPs can be used for through hole wave solder process-
ing 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. Short circuit may be applied to ground or to either supply.
2.
JA
is measured with the component mounted on an evaluation PC board in free air.
Electrical Specifications
PARAMETER
Input Offset Voltage
Input Offset Voltage
Temperature Drift
Input Offset Current
Input Current
Large-Signal Voltage Gain
T
A
= 25
o
C, V+ = 15V, V- = 0V, Unless Otherwise Specified
TEST
CONDITIONS
V
S
=
7.5V
CA3130
MIN
-
-
V
S
=
7.5V
V
S
=
7.5V
V
O
= 10V
P-P
R
L
= 2k
-
-
50
94
70
0
V
S
=
7.5V
R
L
= 2k
R
L
= 2k
R
L
=
R
L
=
-
12
-
14.99
-
12
12
-
-
TYP
8
10
0.5
5
320
110
90
-0.5 to 12
32
13.3
0.002
15
0
22
20
10
2
MAX
15
-
30
50
-
-
-
10
320
-
0.01
-
0.01
45
45
15
3
MIN
-
-
-
-
50
94
80
0
-
12
-
14.99
-
12
12
-
-
CA3130A
TYP
2
10
0.5
5
320
110
90
-0.5 to 12
32
13.3
0.002
15
0
22
20
10
2
MAX
5
-
20
30
-
-
-
10
150
-
0.01
-
0.01
45
45
15
3
UNITS
mV
V/
o
C
pA
pA
kV/V
dB
dB
V
V/V
V
V
V
V
mA
mA
mA
mA
SYMBOL
|V
IO
|
V
IO
/T
|I
IO
|
I
I
A
OL
Common-Mode
Rejection Ratio
Common-Mode Input
Voltage Range
Power-Supply
Rejection Ratio
Maximum Output Voltage
CMRR
V
ICR
V
IO
/V
S
V
OM
+
V
OM
-
V
OM
+
V
OM
-
Maximum Output Current
I
OM
+ (Source) at V
O
= 0V
I
OM
- (Sink) at V
O
= 15V
Supply Current
I+
I+
V
O
= 7.5V,
R
L
=
V
O
= 0V,
R
L
=
FN817 Rev.6.00
Aug 1, 2005
Page 2 of 17
CA3130, CA3130A
Electrical Specifications
Typical Values Intended Only for Design Guidance, V
SUPPLY
= ±7.5V, T
A
= 25
o
C
Unless Otherwise Specified
SYMBOL
TEST CONDITIONS
10k Across Terminals 4 and 5 or
4 and 1
R
I
C
I
e
N
f = 1MHz
BW = 0.2MHz, R
S
= 1M
(Note 3)
C
C
= 0
C
C
= 47pF
CA3130,
CA3130A
22
1.5
4.3
23
15
4
UNITS
mV
T
pF
V
MHz
MHz
PARAMETER
Input Offset Voltage Adjustment Range
Input Resistance
Input Capacitance
Equivalent Input Noise Voltage
Open Loop Unity Gain Crossover Frequency
(For Unity Gain Stability
47pF
Required.)
Slew Rate:
Open Loop
Closed Loop
Transient Response:
Rise Time
Overshoot
Settling Time (To <0.1%, V
IN
= 4V
P-P
)
NOTE:
f
T
SR
C
C
= 0
C
C
= 56pF
C
C
= 56pF,
C
L
= 25pF,
R
L
= 2k
(Voltage Follower)
30
10
V/s
V/s
t
r
OS
t
S
0.09
10
1.2
s
%
s
3. Although a 1M source is used for this test, the equivalent input noise remains constant for values of R
S
up to 10M
Electrical Specifications
PARAMETER
Input Offset Voltage
Input Offset Current
Input Current
Common-Mode Rejection Ratio
Large-Signal Voltage Gain
Typical Values Intended Only for Design Guidance, V+ = 5V, V- = 0V, T
A
= 25
o
C
Unless Otherwise Specified (Note 4)
SYMBOL
V
IO
I
IO
I
I
CMRR
A
OL
V
O
= 4V
P-P
, R
L
= 5k
TEST CONDITIONS
CA3130
8
0.1
2
80
100
100
CA3130A
2
0.1
2
90
100
100
0 to 2.8
300
500
200
UNITS
mV
pA
pA
dB
kV/V
dB
V
A
A
V/V
Common-Mode Input Voltage Range
Supply Current
V
ICR
I+
V
O
= 5V, R
L
=
V
O
= 2.5V, R
L
=
0 to 2.8
300
500
200
Power Supply Rejection Ratio
NOTE:
V
IO
/V+
4. Operation at 5V is not recommended for temperatures below 25
o
C.
FN817 Rev.6.00
Aug 1, 2005
Page 3 of 17
CA3130, CA3130A
Schematic Diagram
BIAS CIRCUIT
Q
1
D
1
Z
1
8.3V
R
1
40k R
2
5k
INPUT STAGE
NON-INV.
INPUT
+
INV.-INPUT
2
3
D
5
D
6
(NOTE 5) D
7
D
8
OUTPUT
STAGE
Q
6
Q
7
SECOND
STAGE
D
2
D
3
D
4
Q
4
Q
5
CURRENT SOURCE FOR
Q
6
AND Q
7
Q
2
“CURRENT SOURCE
LOAD” FOR Q
11
Q
3
7
V+
Q
8
OUTPUT
6
-
R
3
1k
Q
9
Q
10
R
4
1k
Q
11
R
5
1k
R
6
1k
Q
12
5
OFFSET NULL
1
COMPENSATION
8
STROBING
4
V-
NOTE:
5. Diodes D
5
through D
8
provide gate-oxide protection for MOSFET input stage.
Application Information
Circuit Description
Figure 1 is a block diagram of the CA3130 Series CMOS
Operational Amplifiers. The input terminals may be operated
down to 0.5V below the negative supply rail, and the output
can be swung very close to either supply rail in many
applications. Consequently, the CA3130 Series circuits are
ideal for single-supply operation. Three Class A amplifier
stages, having the individual gain capability and current
consumption shown in Figure 1, provide the total gain of the
CA3130. A biasing circuit provides two potentials for common
use in the first and second stages.
Terminal 8 can be used both for phase compensation and 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 potential at Terminal 6 essentially
rises to the positive supply-rail potential at Terminal 7. This
condition of essentially zero current drain in the output stage
under the strobed “OFF” condition can only be achieved when
the ohmic load resistance presented to the amplifier is very
high (e.g.,when the amplifier output is used to drive CMOS
digital circuits in Comparator applications).
Input Stage
The circuit of the CA3130 is shown in the schematic diagram. It
consists of a differential-input stage using PMOS field-effect
transistors (Q
6
, Q
7
) working into a mirror-pair of bipolar
transistors (Q
9
, Q
10
) functioning as load resistors together with
resistors R
3
through R
6
.
The mirror-pair transistors also function as a differential-to-
single-ended converter to provide base drive to the second-
stage bipolar transistor (Q
11
). Offset nulling, when desired, can
be effected by connecting a 100,000 potentiometer across
Terminals 1 and 5 and the potentiometer slider arm to Terminal
4.
FN817 Rev.6.00
Aug 1, 2005
Page 4 of 17
CA3130, CA3130A
V+
7
200A
1.35mA
200A
BIAS CKT.
8mA
(NOTE 5)
0mA
(NOTE 7)
CA3130
in Q
2
and Q
3
as constant current sources for both the first and
second amplifier stages, respectively.
At total supply voltages somewhat less than 8.3V, zener diode
Z
1
becomes nonconductive and the potential, developed
across series-connected R
1
, D
1
-D
4
, and Q
1
, varies directly
with variations in supply voltage. Consequently, the gate bias
for Q
4
, Q
5
and Q
2
, Q
3
varies in accordance with supply-
voltage variations. This variation results in deterioration of the
power-supply-rejection ratio (PSRR) at total supply voltages
below 8.3V. Operation at total supply voltages below about
4.5V results in seriously degraded performance.
+
3
INPUT
2
A
V
5X
A
V
6000X
A
V
30X
OUTPUT
6
V-
4
5
1
C
C
COMPENSATION
(WHEN REQUIRED)
8
STROBE
-
Output Stage
The output stage consists of a drain-loaded inverting amplifier
using CMOS transistors operating in the Class A mode. When
operating into very high resistance loads, the output can be
swung within millivolts of either supply rail. Because the output
stage is a drain-loaded amplifier, its gain is dependent upon
the load impedance. The transfer characteristics of the output
stage for a load returned to the negative supply rail are shown
in Figure 2. Typical op amp loads are readily driven by the
output stage. Because large-signal excursions are non-linear,
requiring feedback for good waveform reproduction, transient
delays may be encountered. As a voltage follower, the
amplifier can achieve 0.01% accuracy levels, including the
negative supply rail.
NOTE:
8. For general information on the characteristics of CMOS transistor-
pairs in linear-circuit applications, see File Number 619, data sheet
on CA3600E “CMOS Transistor Array”.
OUTPUT VOLTAGE (TERMINALS 4 AND 8) (V)
17.5
15
12.5
1k
10
7.5
5
2.5
0
0
2.5
5
7.5
10
12.5
15
17.5
20
22.5
GATE VOLTAGE (TERMINALS 4 AND 8) (V)
500
OFFSET
NULL
NOTES:
6. Total supply voltage (for indicated voltage gains) = 15V with input
terminals biased so that Terminal 6 potential is +7.5V above
Terminal 4.
7. Total supply voltage (for indicated voltage gains) = 15V with
output terminal driven to either supply rail.
FIGURE 1. BLOCK DIAGRAM OF THE CA3130 SERIES
Cascade-connected PMOS transistors Q2, Q4 are the constant-
current source for the input stage. The biasing circuit for the
constant-current source is subsequently described.
The small diodes D
5
through D
8
provide gate-oxide protection
against high-voltage transients, including static electricity during
handling for Q
6
and Q
7
.
Second-Stage
Most of the voltage gain in the CA3130 is provided by the
second amplifier stage, consisting of bipolar transistor Q
11
and
its cascade-connected load resistance provided by PMOS
transistors Q
3
and Q
5
. The source of bias potentials for these
PMOS transistors is subsequently described. Miller Effect
compensation (roll-off) is accomplished by simply connecting a
small capacitor between Terminals 1 and 8. A 47pF capacitor
provides sufficient compensation for stable unity-gain
operation in most applications.
SUPPLY VOLTAGE: V+ = 15, V- = 0V
T
A
= 25
o
C
LOAD RESISTANCE = 5k
2k
Bias-Source Circuit
At total supply voltages, somewhat above 8.3V, resistor R
2
and
zener diode Z
1
serve to establish a voltage of 8.3V across the
series-connected circuit, consisting of resistor R
1
, diodes D
1
through D
4
, and PMOS transistor Q
1
. A tap at the junction of
resistor R
1
and diode D
4
provides a gate-bias potential of about
4.5V for PMOS transistors Q
4
and Q
5
with respect to Terminal 7.
A potential of about 2.2V is developed across diode-connected
[i=s] This post was last edited by paulhyde on 2014-9-15 03:07 [/i] Title: Use a 555 and a 324 to generate four waveforms, a pulse wave, a sawtooth wave, and two sine waves (one with the same frequenc...
With the rapid increase in the speed requirements in recent years, new bus protocols have continuously proposed higher speeds. Traditional bus protocols can no longer meet the requirements. Serial bus...
I'm currently studying Altera's DE2 development board and would like to find some Chinese information about it. Chinese information about Nios II is also fine. I hope you can give me some advice. Than...
Why can't my sjf6410.exe burn the external K9F2G08? Is there something wrong with the configuration? Or does sjf6410.exe not support burning K9F2G08?...
The fuel gauge has three security modes: SEALED (locked), UNSEALED (unlocked), and FULL ACCESS (full access). Different security passwords are required to switch between different security modes. The ...
Without you, I am like a diode, sticking to one direction; without you, I am like an LED, but without a power source to light it up; without you, I am like a transistor, but without the conditions to ...
A single-chip microcomputer is also called a single-chip microcontroller. It is not a chip that completes a certain logical function, but a computer system integrated into one chip. In general, a c...[Details]
Sailing is gaining more and more attention. How to use modern technology to assist training and improve competition results is particularly important. Considering the real-time data collection in t...[Details]
1 Introduction
A wide variety of communication cables and control cables are widely used in various instruments and control equipment. Whether the cable is well-conducted and
whether
th...[Details]
Due to the significant increase in electronic devices in automotive and industrial applications, the automotive and industrial markets continue to play an important role in China's electronics in...[Details]
Abstract: In order to generate a stable excitation signal, the design of a digital frequency synthesizer is implemented on FPGA using Verilog hardware language. The design includes accumulator, wav...[Details]
Introduction
Power subsystems are becoming more and more integrated into the overall system. Power systems have moved from being separate "essential dangerous devices" to being monitorable...[Details]
From the PIC16F946 datasheet, we know that there are two ways to write values to the LCD for display:
1. Directly write the value to LCDDATA1~LCDDATA23
2. Use disconnect t...[Details]
1 Introduction
Intelligent control instruments are one of the most commonly used controllers in industrial control. They are mainly aimed at a specific parameter (such as pressure, tempera...[Details]
MediaTek (2454) announced the acquisition of F-MStar (3697) and attracted the attention of IC design industry. This morning, Gartner Semiconductor Industry Research Director Hong Cenwei analyzed ...[Details]
On the afternoon of July 10, Beijing time, Taiwan's largest chip designer MediaTek expects its smartphone chip shipments to grow by double digits in the third quarter of this year, and the company is ...[Details]
Nippon Electric Works and Volvo Technology Japan have developed a wireless power supply system for electric vehicles (EVs). Using this system, the two companies have successfully conducted an exper...[Details]
This controller uses PIC16C54 single-chip microcomputer as the controller, and it is very easy to use: just connect a telephone line to the loudspeaker through the controller, and you can rem...[Details]
Among the many members of the single-chip microcomputer family, the MCS-51 series of single-chip microcomputers has occupied the main market of industrial measurement and control and automation eng...[Details]
From the previous section, we have learned that the timer/counter in the microcontroller can have multiple uses, so how can I make them work for the purpose I need? This requires setting the timer/...[Details]
1. Disadvantages of choosing too high a voltage level
Choosing too high a voltage level will result in too high an investment and a long payback period. As the voltage level increases, the...[Details]
Electronics Design Contest
京公网安备 11010802033920号
EEWORLD
