NSC LMC6042AIN Cmos dual micropower operational amplifier Datasheet

LMC6042
CMOS Dual Micropower Operational Amplifier
General Description
Features
Ultra-low power consumption and low input-leakage current
are the hallmarks of the LMC6042. Providing input currents
of only 2 fA typical, the LMC6042 can operate from a single
supply, has output swing extending to each supply rail, and
an input voltage range that includes ground.
The LMC6042 is ideal for use in systems requiring ultra-low
power consumption. In addition, the insensitivity to latch-up,
high output drive, and output swing to ground without requiring external pull-down resistors make it ideal for
single-supply battery-powered systems.
Other applications for the LMC6042 include bar code reader
amplifiers, magnetic and electric field detectors, and
hand-held electrometers.
This device is built with National’s advanced Double-Poly
Silicon-Gate CMOS process.
See the LMC6041 for a single, and the LMC6044 for a quad
amplifier with these features.
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Low supply current: 10 µA/Amp (typ)
Operates from 4.5V to 15V single supply
Ultra low input current: 2 fA (typ)
Rail-to-rail output swing
Input common-mode range includes ground
Applications
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Battery monitoring and power conditioning
Photodiode and infrared detector preamplifier
Silicon based transducer systems
Hand-held analytic instruments
pH probe buffer amplifier
Fire and smoke detection systems
Charge amplifier for piezoelectric transducers
Connection Diagram
8-Pin DIP/SO
DS011137-1
Ordering Information
Temperature
Package
Range
NSC
Industrial
Drawing
Transport
Media
−40˚C to +85˚C
8-Pin
LMC6042AIM
Small Outline
LMC6042IM
8-Pin
LMC6042AIN
Molded DIP
LMC6042IN
© 1999 National Semiconductor Corporation
DS011137
M08A
Rail
Tape and Reel
N08E
Rail
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LMC6042 CMOS Dual Micropower Operational Amplifier
August 1999
Absolute Maximum Ratings (Note 1)
Storage Temperature Range
Junction Temperature (Note 3)
ESD Tolerance (Note 4)
Voltage at Input/Output Pin
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
± Supply Voltage
Differential Input Voltage
Supply Voltage (V+ − V−)
Output Short Circuit to V+
Output Short Circuit to V−
Lead Temperature
(Soldering, 10 seconds)
Current at Input Pin
Current at Output Pin
Current at Power Supply Pin
Power Dissipation
−65˚C to +150˚C
110˚C
500V
(V+) + 0.3V, (V−) − 0.3V
Operating Ratings
16V
(Note 12)
(Note 2)
Temperature Range
LMC6042AI, LMC6042I
Supply Voltage
Power Dissipation
Thermal Resistance (θJA), (Note 11)
8-Pin DIP
8-Pin SO
260˚C
± 5 mA
± 18 mA
35 mA
(Note 3)
−40˚C ≤ TJ ≤ +85˚C
4.5V ≤ V+ ≤ 15.5V
(Note 10)
101˚C/W
165˚C/W
Electrical Characteristics
Unless otherwise spec ified, all limits guaranteed for TA = TJ = 25˚C. Boldface limits apply at the temperature extremes. V+ =
5V, V− = 0V, VCM = 1.5V, VO = V+/2 and RL > 1M unless otherwise specified.
Typical
Symbol
VOS
TCVOS
Parameter
Conditions
(Note 5)
Input Offset Voltage
1
Input Offset Voltage
LMC6042AI
LMC6042I
Units
Limit
Limit
(Limit)
(Note 6)
(Note 6)
3
6
mV
3.3
6.3
Max
1.3
µV/˚C
Average Drift
IB
Input Bias Current
0.002
4
4
pA (Max)
IOS
Input Offset Current
0.001
2
2
pA (Max)
RIN
Input Resistance
CMRR
Common Mode
68
62
dB
66
60
Min
68
62
dB
66
60
Min
84
74
dB
83
73
Min
−0.1
−0.1
V
0
0
Max
V+− 2.3V
V+− 2.3V
V
V+− 2.5V
V+− 2.4V
Min
V/mV
0V ≤ VCM ≤ 12.0V
V+ = 15V
75
5V ≤ V+ ≤ 15V
VO = 2.5V
75
94
Input Common-Mode
0V ≤ V− ≤ −10V
VO = 2.5V
V+ = 5V and 15V
Voltage Range
For CMRR ≥ 50 dB
Rejection Ratio
+PSRR
Positive Power Supply
Rejection Ratio
−PSRR
Negative Power Supply
Rejection Ratio
CMR
> 10
−0.4
V+−1.9V
AV
Large Signal
RL = 100 kΩ (Note 7)
Sourcing
1000
Voltage Gain
RL = 25 kΩ (Note 7)
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2
TeraΩ
400
300
300
200
Min
90
V/mV
Sinking
500
180
120
70
Min
Sourcing
1000
200
100
V/mV
160
80
Min
Sinking
250
100
50
V/mV
60
40
Min
Electrical Characteristics
(Continued)
Unless otherwise spec ified, all limits guaranteed for TA = TJ = 25˚C. Boldface limits apply at the temperature extremes. V+ =
5V, V− = 0V, VCM = 1.5V, VO = V+/2 and RL > 1M unless otherwise specified.
Typical
Symbol
Parameter
Output Swing
VO
Conditions
(Note 5)
V+ = 5V
RL = 100 kΩ to V+/2
4.987
0.004
V+ = 5V
RL = 25 kΩ to V+/2
4.980
0.010
V+ = 15V
RL = 100 kΩ to V+/2
14.970
0.007
V+ = 15V
RL = 25 kΩ to V+/2
14.950
0.022
ISC
Output Current
V+ = 5V
Sourcing, VO = 0V
22
Sinking, VO = 5V
ISC
Output Current
V+ = 15V
21
Sourcing, VO = 0V
40
Sinking, VO = 13V
39
(Note 12)
IS
Supply Current
Both Amplifiers
VO = 1.5V
20
Both Amplifiers
V+ = 15V
26
LMC6042AI
LMC6042I
Units
Limit
Limit
(Limit)
(Note 6)
(Note 6)
4.970
4.940
V
4.950
4.910
Min
0.030
0.060
V
0.050
0.090
Max
4.920
4.870
V
4.870
4.820
Min
0.080
0.130
V
0.130
0.180
Max
14.920
14.880
V
14.880
14.820
Min
0.030
0.060
V
0.050
0.090
Max
14.900
14.850
V
14.850
14.800
Min
0.100
0.150
V
0.150
0.200
Max
16
13
mA
10
8
Min
16
13
mA
8
8
Min
15
15
mA
10
10
Min
24
21
mA
8
8
Min
34
45
µA
39
50
Max
44
56
µA
51
65
Max
AC Electrical Characteristics
Unless otherwise specified, all limits guaranteed for TA = TJ = 25˚C. Boldface limits apply at the temperature extremes. V+ =
5V, V− = 0V, VCM = 1.5V, VO = V+/2 and RL > 1M unless otherwise specified.
Symbol
SR
Parameter
Slew Rate
GBW
Gain-Bandwidth Product
φm
Phase Margin
Amp-to-Amp Isolation
en
in
Input-Referred
Voltage Noise
Input-Referred
Current Noise
Conditions
(Note 8)
Typ
LMC6042AI
LMC6042I
Units
(Note 5)
Limit
Limit
(Limit)
(Note 6)
(Note 6)
0.015
0.010
0.010
0.007
0.02
(Note 9)
f = 1 kHz
V/µs
Min
100
kHz
60
Deg
115
dB
83
f = 1 kHz
0.0002
3
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AC Electrical Characteristics
(Continued)
Unless otherwise specified, all limits guaranteed for TA = TJ = 25˚C. Boldface limits apply at the temperature extremes. V+ =
5V, V− = 0V, VCM = 1.5V, VO = V+/2 and RL > 1M unless otherwise specified.
Symbol
T.H.D.
Parameter
Total Harmonic Distortion
Conditions
f = 1 kHz, AV = −5
RL = 100 kΩ, VO = 2 VPP
Typ
LMC6042AI
LMC6042I
Units
(Note 5)
Limit
Limit
(Limit)
(Note 6)
(Note 6)
%
0.01
± 5V Supply
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Conditions indicate conditions for which the device is
intended to be functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The
guaranteed specifications apply only for the test conditions listed.
Note 2: Applies to both single-supply operation. Continuous short circuit operation at elevated ambient temperature can result in exceeding the maximum allowed
junction temperature of 110˚C. Output currents in excess of ± 30 mA over long term may adversely affect reliability.
Note 3: The maximum power dissipation is a function of TJ(Max), θJA, and TA. The maximum allowable power dissipation at any ambient temperature is PD = (TJ(Max)
− TA)/θJA.
Note 4: Human body model, 1.5 kΩ in series with 100 pF.
Note 5: Typical values represent the most likely parametric norm.
Note 6: All limits are guaranteed at room temperature (standard type face) or at operating temperature extremes (bold face type).
Note 7: V+ = 15V, VCM = 7.5V and RL connected to 7.5V. For Sourcing tests, 7.5V ≤ VO ≤ 11.5V. For Sinking tests, 2.5V ≤ VO ≤ 7.5V.
Note 8: V+ = 15V. Connected as Voltage Follower with 10V step input. Number specified is the slower of the positive and negative slew rates.
Note 9: Input referred V+ = 15V and RL = 100 kΩ connected to V+/2. Each amp excited in turn with 100 Hz to produce VO = 12 VPP.
Note 10: For operating at elevated temperatures the device must be derated based on the thermal resistance θJA with PD = (TJ − TA)/θJA.
Note 11: All numbers apply for packages soldered directly into a PC board.
Note 12: Do not connect output to V+when V+ is greater than 13V or reliability may be adversely affected.
Typical Performance Characteristics
Supply Current vs
Supply Voltage
VS = ± 7.5V, TA = 25˚C unless otherwise specified
Offset Voltage vs
Temperature of Five
Representative Units
Input Bias Current
vs Temperature
DS011137-19
DS011137-21
DS011137-20
Input Bias Current
vs Input Common-Mode
Voltage
Input Common-Mode
Voltage Range
vs Temperature
DS011137-22
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Output Characteristics
Current Sinking
DS011137-23
4
DS011137-24
Typical Performance Characteristics
Output Characteristics
Current Sourcing
VS = ± 7.5V, TA = 25˚C unless otherwise specified (Continued)
Input Voltage Noise
vs Frequency
DS011137-25
CMRR vs Frequency
Crosstalk Rejection
vs Frequency
DS011137-26
CMRR vs Temperature
DS011137-27
Power Supply Rejection
Ratio vs Frequency
DS011137-29
DS011137-28
DS011137-30
Open-Loop Voltage
Gain vs Temperature
Open-Loop
Frequency Response
DS011137-31
Gain and Phase
Responses vs
Load Capacitance
DS011137-32
DS011137-33
5
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Typical Performance Characteristics
Gain and Phase
Response vs
Temperature
VS = ± 7.5V, TA = 25˚C unless otherwise specified (Continued)
Gain Error
(VOS vs VOUT)
Common-Mode Error vs
Common-Mode Voltage of
3 Representative Units
DS011137-35
DS011137-34
Non-Inverting Slew
Rate vs Temperature
DS011137-36
Inverting Slew Rate
vs Temperature
DS011137-37
Non-Inverting Large
Signal Pulse Response
(AV = +1)
DS011137-38
DS011137-39
Non-Inverting Small
Signal Pulse Response
Inverting Large-Signal
Pulse Response
DS011137-41
DS011137-40
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Inverting Small Signal
Pulse Response
6
DS011137-42
Typical Performance Characteristics
VS = ± 7.5V, TA = 25˚C unless otherwise specified (Continued)
Stability vs Capacitive Load
Stability vs Capacitive Load
DS011137-43
DS011137-44
Applications Hints
The effect of input capacitance can be compensated for by
adding a capacitor. Place a capacitor, Cf, around the feedback resistor (as in Figure 1 ) such that:
AMPLIFIER TOPOLOGY
The LMC6042 incorporates a novel op-amp design topology
that enables it to maintain rail-to-rail output swing even when
driving a large load. Instead of relying on a push-pull unity
gain output buffer stage, the output stage is taken directly
from the internal integrator, which provides both low output
impedance and large gain. Special feed-forward compensation design techniques are incorporated to maintain stability
over a wider range of operating conditions than traditional
micropower op-amps. These features make the LMC6042
both easier to design with, and provide higher speed than
products typically found in this ultra-low power class.
or
R1 CIN ≤ R2 Cf
Since it is often difficult to know the exact value of CIN, Cf can
be experimentally adjusted so that the desired pulse response is achieved. Refer to the LMC660 and the LMC662
for a more detailed discussion on compensating for input capacitance.
COMPENSATING FOR INPUT CAPACITANCE
It is quite common to use large values of feedback resistance with amplifiers with ultra-low input curent, like the
LMC6042.
Although the LMC6042 is highly stable over a wide range of
operating conditions, certain precautions must be met to
achieve the desired pulse response when a large feedback
resistor is used. Large feedback resistors and even small
values of input capacitance, due to transducers, photodiodes, and circuit board parasitics, reduce phase margins.
When high input impedances are demanded, guarding of the
LMC6042 is suggested. Guarding input lines will not only reduce leakage, but lowers stray input capacitance as well.
(See Printed-Circuit-Board Layout for High Impedance
Work).
CAPACITIVE LOAD TOLERANCE
Direct capacitive loading will reduce the phase margin of
many op-amps. A pole in the feedback loop is created by the
combination of the op-amp’s output impedance and the capacitive load. This pole induces phase lag at the unity-gain
crossover frequency of the amplifier resulting in either an oscillatory or underdamped pulse response. With a few external components, op amps can easily indirectly drive capacitive loads, as shown in Figure 2.
DS011137-6
DS011137-5
FIGURE 2. LMC6042 Noninverting Gain of 10 Amplifier,
Compensated to Handle Capacitive Loads
FIGURE 1. Cancelling the Effect of Input Capacitance
In the circuit of Figure 2, R1 and C1 serve to counteract the
loss of phase margin by feeding the high frequency compo7
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Applications Hints
(Continued)
nent of the output signal back to the amplifier’s inverting input, thereby preserving phase margin in the overall feedback
loop.
Capacitive load driving capability is enhanced by using a
pull up resistor to V+ (Figure 3). Typically a pull up resistor
conducting 10 µA or more will significantly improve capacitive load responses. The value of the pull up resistor must be
determined based on the current sinking capability of the
amplifier with respect to the desired output swing. Open loop
gain of the amplifier can also be affected by the pull up resistor (see Electrical Characteristics).
DS011137-18
DS011137-7
FIGURE 3. Compensating for Large
Capacitive Loads with a Pull Up Resistor
FIGURE 4. Example of Guard Ring
in P.C. Board Layout
PRINTED-CIRCUIT-BOARD LAYOUT FOR
HIGH-IMPEDANCE WORK
It is generally recognized that any circuit which must operate
with less than 1000 pA of leakage current requires special
layout of the PC board. When one wishes to take advantage
of the ultra-low bias current of the LMC6042, typically less
than 2 fA, it is essential to have an excellent layout. Fortunately, the techniques of obtaining low leakages are quite
simple. First, the user must not ignore the surface leakage of
the PC board, even though it may sometimes appear acceptably low, because under conditions of high humidity or dust
or contamination, the surface leakage will be appreciable.
To minimize the effect of any surface leakage, lay out a ring
of foil completely surrounding the LMC6042’s inputs and the
terminals of capacitors, diodes, conductors, resistors, relay
terminals etc. connected to the op-amp’s inputs, as in Figure
4. To have a significant effect, guard rings should be placed
on both the top and bottom of the PC board. This PC foil
must then be connected to a voltage which is at the same
voltage as the amplifier inputs, since no leakage current can
flow between two points at the same potential. For example,
a PC board trace-to-pad resistance of 1012Ω, which is normally considered a very large resistance, could leak 5 pA if
the trace were a 5V bus adjacent to the pad of the input. This
would cause a 100 times degradation from the LMC6042’s
actual performance. However, if a guard ring is held within 5
mV of the inputs, then even a resistance of 1011Ω would
cause only 0.05 pA of leakage current. See Figure 5 for typical connections of guard rings for standard op-amp
configurations.
DS011137-8
Inverting Amplifier
DS011137-10
Non-Inverting Amplifier
DS011137-9
Follower
FIGURE 5. Typical Connections of Guard Rings
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8
Applications Hints
probes, analytic medical instruments, magnetic field detectors, gas detectors, and silicon based pressure transducers.
The circuit in Figure 7 is recommended for applications
where the common-mode input range is relatively low and
the differential gain will be in the range of 10 to 1000. This
two op-amp instrumentation amplifier features an independent adjustment of the gain and common-mode rejection
trim, and a total quiescent supply current of less than 20 µA.
To maintain ultra-high input impedance, it is advisable to use
ground rings and consider PC board layout an important part
of the overall system design (see Printed-Circuit-Board Layout for High Impedance Work). Referring to Figure 7, the input voltages are represented as a common-mode input VCM
plus a differential input VD.
Rejection of the common-mode component of the input is
accomplished by making the ratio of R1/R2 equal to R3/R4.
So that where,
(Continued)
The designer should be aware that when it is inappropriate
to lay out a PC board for the sake of just a few circuits, there
is another technique which is even better than a guard ring
on a PC board: Don’t insert the amplifier’s input pin into the
board at all, but bend it up in the air and use only air as an insulator. Air is an excellent insulator. In this case you may
have to forego some of the advantages of PC board construction, but the advantages are sometimes well worth the
effort of using point-to-point up-in-the-air wiring. See Figure
6.
A suggested design guideline is to minimize the difference of
value between R1 through R4. This will often result in improved resistor tempco, amplifier gain, and CMRR over temperature. If RN = R1 = R2 = R3 = R4 then the gain equation
can be simplified:
DS011137-11
(Input pins are lifted out of PC board and soldered directly to components.
All other pins connected to PC board.)
FIGURE 6. Air Wiring
Typical Single-Supply Applications
(V+ = 5.0 VDC)
The extremely high input impedance, and low power consumption, of the LMC6042 make it ideal for applications that
require battery-powered instrumentation amplifiers. Examples of these types of applications are hand-held pH
Due to the “zero-in, zero-out” performance of the LMC6042,
and output swing rail-rail, the dynamic range is only limited to
the input common-mode range of 0V to VS − 2.3V, worst
case at room temperature. This feature of the LMC6042
makes it an ideal choice for low-power instrumentation systems.
A complete instrumentation amplifier designed for a gain of
100 is shown in Figure 8. Provisions have been made for low
sensitivity trimming of CMRR and gain.
DS011137-12
FIGURE 7. Two Op-Amp Instrumentation Amplifier
9
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Typical Single-Supply Applications
(V+ = 5.0 VDC) (Continued)
DS011137-13
FIGURE 8. Low-Power Two-Op-Amp
Instrumentation Amplifier
DS011137-14
FIGURE 9. Low-Leakage Sample and Hold
DS011137-15
FIGURE 10. Instrumentation Amplifier
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Typical Single-Supply Applications
(V+ = 5.0 VDC) (Continued)
DS011137-16
FIGURE 11. 1 Hz Square Wave Oscillator
DS011137-17
FIGURE 12. AC Coupled Power Amplifier
11
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Physical Dimensions
inches (millimeters) unless otherwise noted
8-Pin Small Outline Package
Order Number LMC6042AIM or LMC6042IM
NS Package Number M08A
8-Pin Molded Dual-In-Line Package
Order Number LMC6042AIN or LMC6042IN
NS Package Number N08E
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LMC6042 CMOS Dual Micropower Operational Amplifier
Notes
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accordance with instructions for use provided in the
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