NSC LMC2001AIM

LMC2001
High Precision, 6MHz Rail-To-Rail Output Operational
Amplifier
General Description
Features
The LMC2001 is a new precision amplifier that offers unprecedented accuracy and stability at an affordable price
and is offered in miniature (SOT23-5) package. This device
utilizes patented techniques to measure and continually correct the input offset error voltage. The result is an amplifier
which is ultra stable over time, and temperature. It has excellent CMRR and PSRR ratings, and does not exhibit the familiar 1/f voltage and current noise increase that plagues traditional amplifiers. The combination of the LMC2001
characteristics makes it a good choice for transducer amplifiers, high gain configurations, ADC buffer amplifiers, DAC
I-V conversion, and any other 5V application requiring precision and/or stability.
Other useful benefits of the LMC2001 are rail-to-rail output,
low supply current of 750µA, and wide gain-bandwidth
product of 6MHz. The LMC2001 comes in 5 pin SOT23 and
8 pin SOIC. These extremely versatile features found in the
LMC2001 provide high performance and ease of use.
(Vs = 5V, RL = 10K to V+ /2, Typ. Unless Noted)
n Low Guaranteed Vos
40µV
n en With No 1/f
85nV/
n High CMRR
120dB
n High PSRR
120dB
n High AVOL
137dB
n Wide Gain-Bandwidth Product
6MHz
n High Slew Rate
5V/µs
n Low Supply Current
750µA
n Rail-To-Rail Output
30mV from either rail
n No External Capacitors Required
Applications
n Precision Instrumentation Amplifiers
n Thermocouple Amplifiers
n Strain Gauge Bridge Amplifier
Connection Diagrams
8-Pin SO
5-Pin SOT23
DS100058-1
DS100058-2
Top View
Top View
Ordering Information
Package
Temperature Range
Commercial
0˚C to +70˚C
Package
Marking
LMC2001AIM
LMC2001AIM
LMC2001AIMX
LMC2001ACM5
LMC2001ACM5X
© 1999 National Semiconductor Corporation
NSC
Drawing
Rails
M08A
Industrial
−40˚C to +85˚C
8-pin Small Outline
5-pin SOT23-5
Transport
Media
DS100058
2.5k Units Tape
and Reel
A09A
1k Units Tape
and Reel
MA05B
3k Units Tape
and Reel
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LMC2001 High Precision, 6MHz Rail-To-Rail Output Operational Amplifier
August 1999
Absolute Maximum Ratings (Note 1)
Storage Temperature Range
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Junction Temperature (TJ )
(Note 4)
-65˚C to 150˚C
150˚C
Operating Ratings (Note 1)
ESD Tolerance (Note 2)
Human Body Model
2500V
Machine Model
Supply voltage
150V
Differential Input Voltage
± Supply Voltage
Supply Voltage (V+ - V-)
5.6V
Current At Input Pin
30mA
Current At Output Pin
30mA
Current At Power Supply Pin
(Note 3)
-40˚C ≤ TJ ≤ 85˚C
LMC2001AI
0˚C ≤ TJ ≤ 70˚C
LMC2001AC
Thermal resistance ( θ
50mA
Lead Temperature (soldering, 10
sec)
4.75V to 5.25V
Temperature Range
JA)
M Package, 8-pin Surface Mount
180˚C /W
M5 Package, SOT23-5
274˚C /W
260˚C
DC Electrical Characteristics
Unless otherwise specified, all limits guaranteed for T
Boldface limits apply at the temperature extremes.
J
= 25˚C, V+ = 5V, V- = 0V, V
CM
= 2.5V, VO = 2.5V and RL > 1MΩ.
Typ
(Note 5)
Limit(Note 6)
(Note 11)
0.5
40
60
5
30
Input Offset Voltage
(Note 12)
0.015
Long-Term Offset Drift
(Note 8)
0.006
Lifetime VOS drift
(Note 8)
2.5
IIN
Input Current
(Note 9)
-3
IOS
Input Offset Current
6
pA
RIND
Input Differential Resistance
9
MΩ
CMRR
Common Mode Rejection
Ratio
Symbol
Parameter
Conditions
VOS
Input Offset Voltage
Offset Calibration Time
TCVOS
Units
µV
max
ms
µV/˚C
µV/month
5
µV Max
pA
0V ≤ VCM ≤ 3.5V
120
100
dB
min
0.1V ≤ VCM ≤ 3.5V
110
90
dB
min
PSRR
Power Supply
Rejection Ratio
4.75V ≤ V+ ≤ 5.25V
120
95
90
dB
min
AVOL
Large Signal Voltage Gain
(Note 7)
RL= 10kΩ
137
105
100
dB
min
RL = 2kΩ
128
95
90
4.975
4.955
4.955
V
min
0.030
0.060
0.060
V
max
VO
IO
IS
Output Swing
Output Current
RL = 10kΩ to 2.5V
VIN(diff) = ± 0.5V
RL = 2kΩ to 2.5V
VIN(diff) = ± 0.5V
4.936
Sourcing, VO = 0V
VIN(diff) = ± 0.5V
5.9
4.1
1.5
mA
min
Sinking, VO = 5V
V IN(diff) = ± 0.5V
14.5
4.5
1.5
mA
min
0.75
1.0
1.2
mA
max
Supply Current
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V
0.075
2
V
AC Electrical Characteristics
TJ = 25˚C, V+ = 5V, V - = 0V, VCM = 2.5V, VO = 2.5V, and RL > 1MΩ.
Conditions
Typ
(Note 5)
Symbol
Parameter
SR
Slew Rate
5
V/µs
GBW
Gain-Bandwidth Product
6
MHz
θm
Phase Margin
75
Deg
Gm
Gain Margin
12
en
Input-Referred Voltage Noise
f = 0.1Hz
AV = +1, Vin=3.5Vpp
85
Units
dB
nV/
enp-p
Input-Referred Voltage Noise
RS = 100Ω, DC to 10Hz
1.6
in
Input-Referred Current Noise
f = 0.1Hz
180
THD
Total Harmonic Distortion
f = 1kHz, Av = -2
RL = 10kΩ,VO = 4.5Vpp
0.02
%
trec
Input Overload Recovery Time
TS
Output Settling time
(Note 10) AV = +1, 1V step
(Note 10)AV = −1, 1V step
µVpp
fA/
50
ms
1%
250
ns
0.1%
400
0.01%
3200
1%
80
0.1%
860
0.01%
1400
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is intended to be functional, but specific performance is not guaranteed. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: Human body model, 1.5kΩ in series with 100pF. Machine model, 200Ω in series with 100pF.
Note 3: Output currents in excess of ± 30mA over long term may adversely affect reliability.
Note 4: The maximum power dissipation is a function of TJ(max), θ JA, and TA. The maximum allowable power dissipation at any ambient temperature is PD = (TJ(max)
- TA)/θ JA. All numbers apply for packages soldered directly onto a PC board.
Note 5: Typical values represent the most likely parametric norm.
Note 6: All limits are guaranteed by testing or statistical analysis, unless otherwise noted.
Note 7: V+ = 5V, VCM = 2.5V, and RL connected to 2.5V. For Sourcing tests, 2.5V ≤ VO ≤ 4.8V. For Sinking tests, 0.2V ≤ V O ≤ 2.5V.
Note 8: Guaranteed Vos Drift is based on 280 devices operated for 1000 hrs at 150˚C (equivalent to 30 years 55ºC).
Note 9: Guaranteed by design only.
Note 10: Settling times shown correspond to the worse case (positive or negative step) and does not include slew time. See the Application Note section for test
schematic.
Note 11: The limits are set by the accuracy of high speed automatic test equipment. For the typical VOS distribution, see the curve on page 4.
Note 12: Precision bench measurement of more than 300 units. More than 65% of units had less than 15nV /˚C VOS drift.
3
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Typical Performance Characteristics
TA = 25C, VS = 5V unless otherwise specified.
VOS Distribution
VOS vs VS
VOS vs VCM
DS100058-63
DS100058-97
DS100058-91
+IIN vs VCM
−IINvs VCM
DS100058-68
eN vs Frequency
DS100058-A4
DS100058-A0
CMR vs VCM
CMR vs Frequency
PSR vs Frequency
DS100058-66
DS100058-65
DS100058-92
VOUT+ vs VS
VOUT+ vs VS
DS100058-89
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VOUT− vs VS
DS100058-88
4
DS100058-99
Typical Performance Characteristics
VOUT− vs VS
(Continued)
Gain-Phase vs VS
Gain-Phase vs Temp
DS100058-98
DS100058-49
DS100058-48
Gain-Phase vs RL
Gain-Phase vs CLOAD
DS100058-50
THD+N vs VOUT
THD+N vs Frequency
DS100058-47
Isink vs VOUT
Isource vs VOUT
DS100058-76
DS100058-A5
DS100058-A7
DS100058-A8
Isupply vs VS
DS100058-96
5
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pulse is 80ns. To recover to 0.1% requires 860ns. This rapid
recovery is due to the wide bandwidth of the output stage
and large total GBW.
Application Notes
The Benefits of LMC2001
No 1/f Noise
Using patented methods, the LMC2001 eliminates the 1/f
noise present in other amplifiers. This noise which increases
as frequency decreases is a major source of measurement
error in all DC coupled measurements. Low frequency noise
appears as a constantly changing signal in series with any
measurement being made. As a result, even when the measurement is made rapidly, this constantly changing noise signal will corrupt the result. The value of this noise signal can
be surprisingly large. For example: If a conventional amplifier has a high frequency noise level of 10nV/
and a
noise corner of 10 Hz, the RMS noise at 0.001 Hz is 1µV/
DS100058-B0
FIGURE 1.
No External Capacitors Required
The LMC2001 does not need external capacitors. This eliminates the problems caused by capacitor leakage and dielectric absorption, which can cause delays of several seconds
from turn-on until the amplifier is settled.
This is equivalent to a 6µV peak-to-peak error. In a circuit
with a gain of 1000, this produces a 6mV peak-to-peak output error. This number of 0.001 Hz might appear unreasonably low but when a data acquisition system is operating for
17 minutes it has been on long enough to include this error.
In this same time, the LMC2001 will only have a 0.51mV output error. This is more than 13.3 times less error.
Keep in mind that this 1/f error gets even larger at lower frequencies.
At the extreme, many people try to reduce this error by integrating or taking several samples of the same signal. This is
also doomed to failure because the 1/f nature of this noise
means that taking longer samples just moves the measurement into lower frequencies where the noise level is even
higher.
The LMC2001 eliminates this source of error. The noise level
is constant with frequency so that reducing the bandwidth reduces the errors caused by noise.
Another source of error that is rarely mentioned is the error
voltages caused by the inadvertent thermocouples created
when the common “Kovar type” package lead materials are
soldered to a copper printed circuit board. These steel based
leadframe materials can produce over 35uV/˚C when soldered onto a copper trace. This can result in thermocouple
noise that is equal to the LMC2001 noise when there is a
temperature difference of only 0.0014˚C between the lead
and the board!
For this reason, the leadframe of the LMC2001 is made of
copper. This results in equal and opposite junctions which
cancel this effect. The extremely small size of the SOT-23
package results in the leads being very close together. This
further reduces the probability of temperature differences
and hence decreases thermal noise.
Overload Recovery
The LMC2001 recovers from input overload much faster
than most chopper stabilized opamps. Recovery, from driving the amplifier to 2X the full scale output, only requires
about 50ms. Most chopper stabilized amplifiers will take
from 250ms to several seconds to recover from this same
overload. This is because large capacitors are used to store
the unadjusted offset voltage.
More Benefits
The LMC2001 offers the benefits mentioned above and
more. It is rail-to-rail output and consumes only 750µA of
supply current while providing excellent DC and AC electrical
performance. In DC performance, the LMC2001 achieves
120dB of CMRR, 120dB of PSRR and 137dB of open loop
gain. In AC performance, the LMC2001 provides 6MHz of
gain-bandwidth product and 5V/µs of slew rate.
How the LMC2001 Works
The LMC2001 uses new, patented techniques to achieve the
high DC accuracy traditionally associated with chopper stabilized amplifiers without the major drawbacks produced by
chopping. The LMC2001 continuously monitors the input offset and corrects this error. The conventional chopping process produces many mixing products, both sums and differences, between the chopping frequency and the incoming
signal frequency. This mixing causes large amounts of distortion, particularly when the signal frequency approaches
the chopping frequency. Even without an incoming signal,
the chopper harmonics mix with each other to produce even
more trash. If this sounds unlikely or difficult to understand,
look at the plot (Figure 2), of the output of a typical (MAX432)
chopper stabilized opamp. This is the output when there is
no incoming signal, just the amplifier in a gain of -10 with the
input grounded. The chopper is operating at about 150Hz,
the rest is mixing products. Add an input signal and the mess
gets much worse. Compare this plot with Figure 3 of the
LMC2001. This data was taken under the exact same conditions. The auto zero action is visible at about 11kHz but note
the absence of mixing products at other frequencies. As a result, the LMC2001 has very low distortion of 0.02% and very
low mixing products.
Input Currents
The LMC2001 input current is different than standard bipolar
or CMOS input currents in that it appears as a current flowing in one input and out the other. Under most operating conditions, these currents are in the picoamp level and will have
little or no effect in most circuits. These currents increase to
the nA level when the common-mode voltage is near the minus supply. (see the typical curves) At high temperatures
such as 85˚C, the input currents become larger, 0.5nA typical, and are both positive except when the Vcm is near V−. If
operation is expected at low common-mode voltages and
high temperature, do not add resistance in series with the inputs to balance the impedances. Doing this can cause an increase in offset voltage.
The wide bandwidth of the LMC2001 enhances performance
when it is used as an amplifier to drive loads that inject transients back into the output. A to Ds and multiplexers are examples of this type of load. To simulate this type of load, a
pulse generator producing a 1V peak square wave was connected to the output through a 10pF capacitor. (Figure 1)
The typical time for the output to recover to 1% of the applied
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6
Application Notes
eration). Higher closed loop gains are also possible with a
corresponding reduction in realizable bandwidth. Table 1
shows some other closed loop gain possibilities along with
the measured performance in each case
(Continued)
Application Circuits
DS100058-A1
FIGURE 2.
DS100058-21
FIGURE 4. Single Supply Strain- Gauge Amplifier
DS100058-A0
FIGURE 3.
This Strain-Gauge (Figure 4) amplifier provides high gain
(1006 or 60 dB) with very low offset and drift. Using the resistors tolerance as shown, the worst case CMRR will be
greater than 90 dB. The common-mode gain is directly related to the resistor mismatch and is independent of the differential gain that is set by R3. The worst case commonmode gain is −54 dB. This gain becomes even lower,
improving CMRR, if the resistor ratio matching is improved.
DS100058-30
FIGURE 5. Inverting Composite Amplifier
Extending Supply Voltages and Output Swing by Using
a Composite Amplifier Configuration:
In cases where substantially higher output swing is required
with higher supply voltages, arrangements like the ones
shown in Figure 5, and Figure 6 could be used (pin numbers
shown are for SO-8 package). These configurations utilize
the excellent DC performance of the LMC2001 while at the
same time allow the superior voltage and frequency capabilities of the LM6171 to set the dynamic performance of the
overall amplifier. For example, it is possible to achieve ± 12V
output swing with 300MHz of overall GBW (Av=100) while
keeping the worst case output shift due to Vos less than
4mV. The LMC2001 output voltage is kept at about mid-point
of it’s overall supply voltage and it’s input common mode
voltage range allows the V- terminal to be grounded in one
case (Figure 5, inverting operation) and tied to a small noncritical negative bias in another (Figure 6, non-inverting op7
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Application Notes
minimize the overall bandwidth. As can be seen from Equation 1 above, the improvement in output noise has a square
law relationship to the reduction in BW.
In the case of the inverting configuration, it is also possible to
increase the input impedance of the overall amplifier, by raising the value of R1, without having to increase the feedback
resistor, R2, to impractical values, by utilizing a “T” network
as feedback. See the LMC6442 data sheet (Application
Notes section) for more details on this.
LMC2001 as ADC Input Amplifier
The LMC2001 is a great choice for an amplifier stage immediately before the input of an A/D converter (AC or DC
coupled) see Figure 7 and Figure 8 because of the following
important characteristics:
a) Very low offset voltage and offset voltage drift over time
and temperature allow a high closed loop gain setting without introducing any short term or long term errors. For example, when set to a closed loop gain of 100 as the analog
input amplifier of a 12 bit A/D converter, the overall conversion error over full operation temperature and 30 years life of
the part (operating at 50˚C) would be less than 5LSB.
b) Fast large signal settling time to 0.01% of final value (1.4
us) allows 12 bit accuracy at 100KHz or more sampling rate.
c) No flicker (1/f) noise means unsurpassed data accuracy
over any measurement period of time, no matter how long.
Consider the following opamp performance, based on a typical commercially available device, for comparison:
(Continued)
DS100058-31
FIGURE 6. Non-Inverting Composite Amplifier
TABLE 1. Composite Amplifier Measured Performance
Av
Opamp flatband noise
8nV/
R1
R2
C2
BW
SR
enpp
(ohm)
(ohm)
(pF)
(MHz)
(V/us)
(mVpp)
50
200
10K
8
3.3
178
37
1/f0.94 corner frequency
100Hz
100
100
10K
10
2.5
174
70
f(max)
100Hz
100
1K
100K
0.67
3.1
170
70
Av
500
200
100K
1.75
1.4
96
250
1000
100
100K
2.2
0.98
64
400
In terms of the measured output peak-to-peak noise, the following relationship holds between output noise voltage, enpp,
for different closed loop gain, Av, settings, where -3dB Bandwidth is BW:
(1)
It should be kept in mind that in order to minimize the output
noise voltage for a given closed loop gain setting, one could
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100
Measurement time
100 sec
The example above, will result in about 3mVpp (2.5LSB) of
output noise contribution due to the opamp alone, compared
to about 420 uVpp (less than 1LSB) when that opamp is replaced with the LMC2001 which has no 1/f contribution. If the
measurement time is increased from 100 sec. to 1 hr., the
improvement realized by using the LMC2001 would be a factor of about 44 times (18.5mVpp compared to 420uV when
LMC2001 is used) mainly because the LMC2001 accuracy is
not compromised by increasing the observation time.
d) Copper lead frame construction minimizes any thermocouple effects which would degrade low level/high gain data
conversion application accuracy (see discussion under “The
Benefits of the LMC2001” section above).
e) Rail-to-Rail output swing maximized the ADC dynamic
range in 5V single supply converter applications. Below are
some typical block diagrams showing the LMC2001 used as
an ADC amplifier (Figure 7 and Figure 8).
8
Application Notes
(Continued)
DS100058-52
FIGURE 7.
DS100058-53
FIGURE 8.
9
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Physical Dimensions
inches (millimeters) unless otherwise noted
M08A
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10
inches (millimeters) unless otherwise noted (Continued)
MA05B
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LMC2001 High Precision, 6MHz Rail-To-Rail Output Operational Amplifier
Physical Dimensions