NSC LMP2014MTX Quad high precision, rail-to-rail output operational amplifier Datasheet

LMP2014MT
Quad High Precision, Rail-to-Rail Output Operational
Amplifier
General Description
Features
TM
The LMP2014MT is a member of National’s new LMP
precision amplifier family. The LMP2014MT offers unprecedented accuracy and stability while also being offered at an
affordable price. 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 LMP2014 characteristics makes it a good choice for
transducer amplifiers, high gain configurations, ADC buffer
amplifiers, DAC I-V conversion, and any other 2.7V-5V application requiring precision and long term stability.
Other useful benefits of the LMP2014 are rail-to-rail output, a
low supply current of 3.7 mA, and wide gain-bandwidth
product of 3 MHz. These extremely versatile features found
in the LMP2014 provide high performance and ease of use.
(For VS = 5V, Typical unless otherwise noted)
n Low guaranteed VOS over temperature
n Low noise with no 1/f
n High CMRR
n High PSRR
n High AVOL
n Wide gain-bandwidth product
n High slew rate
n Low supply current
n Rail-to-rail output
n No external capacitors required
60 µV
35nV/
130 dB
120 dB
130 dB
3 MHz
4 V/µs
3.7 mA
30 mV
Applications
n Precision instrumentation amplifiers
n Thermocouple amplifiers
n Strain gauge bridge amplifier
Connection Diagram
14-Pin TSSOP
20132939
Top View
Ordering Information
Package
Part Number
14-Pin
TSSOP
LMP2014MT
LMP2014MTX
© 2005 National Semiconductor Corporation
Temperature
Range
Package Marking
0˚C to 70˚C
LMP2014MT
DS201329
Transport Media
94 Units/Rail
2.5k Units Tape and Reel
NSC Drawing
MTC14
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LMP2014MT Quad High Precision, Rail-to-Rail Output Operational Amplifier
July 2005
LMP2014MT
Absolute Maximum Ratings (Note 1)
Differential Input Voltage
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Current at Input Pin
± Supply Voltage
30 mA
Current at Output Pin
30 mA
Current at Power Supply Pin
50 mA
ESD Tolerance
Human Body Model
2000V
Machine Model
Operating Ratings (Note 1)
200V
Supply Voltage
Supply Voltage
5.8V
2.7V to 5.25V
Storage Temperature Range
Common-Mode Input
Voltage
−65˚C to 150˚C
Operating Temperature Range
−0.3 ≤ VCM ≤ VCC +0.3V
LMP2014MT, LMP2014MTX
Lead Temperature
(soldering 10 sec.)
0˚C to 70˚C
+300˚C
2.7V DC Electrical Characteristics
V+ = 2.7V, V- = 0V, V
TCVOS
Unless otherwise specified, all limits guaranteed for T J = 25˚C,
= 1.35V, VO = 1.35V and RL > 1 MΩ. Boldface limits apply at the temperature extremes.
Typ
(Note 2)
Max
(Note 3)
Input Offset Voltage
0.8
30
60
µV
Offset Calibration Time
0.5
10
12
ms
Symbol
VOS
CM
Parameter
Conditions
Min
(Note 3)
Units
Input Offset Voltage
0.015
µV/˚C
Long-Term Offset Drift
0.006
µV/month
Lifetime VOS Drift
2.5
µV
IIN
Input Current
-3
pA
IOS
Input Offset Current
6
pA
RIND
Input Differential Resistance
9
MΩ
CMRR
Common Mode Rejection
Ratio
95
90
130
dB
PSRR
Power Supply Rejection Ratio
95
90
120
dB
AVOL
Open Loop Voltage Gain
RL = 10 kΩ
95
90
130
RL = 2 kΩ
90
85
124
2.63
2.655
2.68
VO
Output Swing
−0.3 ≤ VCM ≤ 0.9V
0 ≤ VCM ≤ 0.9V
RL = 10 kΩ to 1.35V
VIN(diff) = ± 0.5V
0.033
RL = 2 kΩ to 1.35V
VIN(diff) = ± 0.5V
2.615
2.615
IS
Output Current
Sourcing, VO = 0V
VIN(diff) = ± 0.5V
5
3
12
Sinking, VO = 5V
VIN(diff) = ± 0.5V
5
3
18
Supply Current per Channel
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0.919
2
0.070
0.075
V
2.65
0.061
IO
dB
0.085
0.105
V
mA
1.20
1.50
mA
TJ = 25˚C, V+ = 2.7V, V - = 0V, VCM = 1.35V, VO = 1.35V, and RL
> 1 MΩ. Boldface limits apply at the temperature extremes.
Symbol
Parameter
GBW
Gain-Bandwidth Product
SR
θm
Conditions
Min
(Note 3)
Typ
(Note 2)
Max
(Note 3)
Units
3
MHz
Slew Rate
4
V/µs
Phase Margin
60
Deg
Gm
Gain Margin
−14
en
Input-Referred Voltage Noise
35
in
Input-Referred Current Noise
enp-p
Input-Referred Voltage Noise
trec
Input Overload Recovery Time
pA/
RS = 100Ω, DC to 10 Hz
850
nVpp
50
ms
5V DC Electrical Characteristics
-
5V, V = 0V, V
Symbol
VOS
CM
dB
nV/
Unless otherwise specified, all limits guaranteed for T
= 2.5V, VO = 2.5V and RL > 1MΩ. Boldface limits apply at the temperature extremes.
= 25˚C, V+ =
Typ
(Note 2)
Max
(Note 3)
Input Offset Voltage
0.12
30
60
µV
Offset Calibration Time
0.5
10
12
ms
Parameter
Conditions
Min
(Note 3)
J
Units
Input Offset Voltage
0.015
µV/˚C
Long-Term Offset Drift
0.006
µV/month
Lifetime VOS Drift
2.5
µV
IIN
Input Current
-3
pA
IOS
Input Offset Current
6
pA
TCVOS
RIND
Input Differential Resistance
CMRR
Common Mode Rejection
Ratio
PSRR
Power Supply Rejection Ratio
AVOL
Open Loop Voltage Gain
VO
Output Swing
9
MΩ
100
90
130
dB
95
90
120
dB
RL = 10 kΩ
105
100
130
RL = 2 kΩ
95
90
132
4.92
4.95
4.978
−0.3 ≤ VCM ≤ 3.2
0 ≤ VCM ≤ 3.2
RL = 10 kΩ to 2.5V
VIN(diff) = ± 0.5V
0.040
4.875
4.875
RL = 2 kΩ to 2.5V
VIN(diff) = ± 0.5V
IS
Output Current
Sourcing, VO = 0V
VIN(diff) = ± 0.5V
8
6
15
Sinking, VO = 5V
V IN(diff) = ± 0.5V
8
6
17
Supply Current per Channel
0.930
3
0.080
0.085
V
4.919
0.091
IO
dB
0.125
0.140
V
mA
1.20
1.50
mA
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LMP2014MT
2.7V AC Electrical Characteristics
LMP2014MT
5V AC Electrical Characteristics
TJ = 25˚C, V+ = 5V, V - = 0V, VCM = 2.5V, VO = 2.5V, and RL >
1MΩ. Boldface limits apply at the temperature extremes.
Symbol
Parameter
GBW
Gain-Bandwidth Product
SR
θm
Conditions
Min
(Note 3)
Typ
(Note 2)
Max
(Note 3)
Units
3
MHz
Slew Rate
4
V/µs
Phase Margin
60
deg
Gm
Gain Margin
−15
en
Input-Referred Voltage Noise
35
in
Input-Referred Current Noise
enp-p
Input-Referred Voltage Noise
trec
Input Overload Recovery Time
dB
nV/
pA/
RS = 100Ω, DC to 10 Hz
850
nVPP
50
ms
Note 1: Absolute Maximum Ratings indicate limits beyond which damage 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: Typical values represent the most likely parametric norm.
Note 3: Limits are 100% production tested at 25˚C. Limits over the operating temperature range are guaranteed through correlations using statistical quality control
(SQC) method.
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4
LMP2014MT
Typical Performance Characteristics
TA=25C, VS= 5V unless otherwise specified.
Supply Current vs. Supply Voltage
Offset Voltage vs. Supply Voltage
20132943
20132944
Offset Voltage vs. Common Mode
Offset Voltage vs. Common Mode
20132945
20132946
Voltage Noise vs. Frequency
Input Bias Current vs. Common Mode
20132903
20132904
5
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LMP2014MT
Typical Performance Characteristics
(Continued)
PSRR vs. Frequency
PSRR vs. Frequency
20132907
20132906
Output Sourcing @ 2.7V
Output Sourcing @ 5V
20132947
20132948
Output Sinking @ 2.7V
Output Sinking @ 5V
20132949
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20132950
6
LMP2014MT
Typical Performance Characteristics
(Continued)
Max Output Swing vs. Supply Voltage
Max Output Swing vs. Supply Voltage
20132951
20132952
Min Output Swing vs. Supply Voltage
Min Output Swing vs. Supply Voltage
20132953
20132954
CMRR vs. Frequency
Open Loop Gain and Phase vs. Supply Voltage
20132908
20132905
7
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LMP2014MT
Typical Performance Characteristics
(Continued)
Open Loop Gain and Phase vs. RL @ 2.7V
Open Loop Gain and Phase vs. RL @ 5V
20132909
20132910
Open Loop Gain and Phase vs. CL @ 2.7V
Open Loop Gain and Phase vs. CL @ 5V
20132912
20132911
Open Loop Gain and Phase vs. Temperature @ 2.7V
Open Loop Gain and Phase vs. Temperature @ 5V
20132936
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20132937
8
LMP2014MT
Typical Performance Characteristics
(Continued)
THD+N vs. AMPL
THD+N vs. Frequency
20132913
20132914
0.1 Hz − 10 Hz Noise vs. Time
20132915
9
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LMP2014MT
Application Information
THE BENEFITS OF LMP2014
NO 1/f NOISE
The wide bandwidth of the LMP2014 enhances performance
when it is used as an amplifier to drive loads that inject
transients back into the output. ADCs (Analog-to-Digital Converters) 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
10 pF capacitor. (Figure 1) The typical time for the output to
recover to 1% of the applied pulse is 80 ns. To recover to
0.1% requires 860ns. This rapid recovery is due to the wide
bandwidth of the output stage and large total GBW.
Using patented methods, the LMP2014 eliminates the 1/f
noise present in other amplifiers. That noise, which increases as frequency decreases, is a major source of measurement error in all DC-coupled measurements. Lowfrequency 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 constantlychanging noise signal will corrupt the result. The value of this
noise signal can be surprisingly large. For example: If a
conventional amplifier has a flat-band noise level of 10nV/
and a noise corner of 10 Hz, the RMS noise at 0.001
. This is equivalent to a 0.50 µV peak-toHz is 1µV/
peak error, in the frequency range 0.001 Hz to 1.0 Hz. In a
circuit with a gain of 1000, this produces a 0.50 mV peakto-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 LMP2014 will only
have a 0.21 mV output error. This is smaller by 2.4 x. 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.
NO EXTERNAL CAPACITORS REQUIRED
The LMP2014 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’s error has settled.
MORE BENEFITS
The LMP2014 offers the benefits mentioned above and
more. It has a rail-to-rail output and consumes only 950 µA of
supply current while providing excellent DC and AC electrical
performance. In DC performance, the LMP2014 achieves
130 dB of CMRR, 120 dB of PSRR and 130 dB of open loop
gain. In AC performance, the LMP2014 provides 3 MHz of
gain-bandwidth product and 4 V/µs of slew rate.
HOW THE LMP2014 WORKS
The LMP2014 uses new, patented techniques to achieve the
high DC accuracy traditionally associated with chopperstabilized amplifiers without the major drawbacks produced
by chopping. The LMP2014 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 op amp. 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 150 Hz;
the rest is mixing products. Add an input signal and the noise
gets much worse. Compare this plot with Figure 3 of the
LMP2014. This data was taken under the exact same conditions. The auto-zero action is visible at about 30 kHz but
note the absence of mixing products at other frequencies. As
a result, the LMP2014 has very low distortion of 0.02% and
very low mixing products.
The LMP2014 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
voltage caused by the inadvertent thermocouples created
when the common "Kovar type" IC package lead materials
are soldered to a copper printed circuit board. These steelbased leadframe materials can produce over 35 µV/˚C when
soldered onto a copper trace. This can result in thermocouple noise that is equal to the LMP2014 noise when there
is a temperature difference of only 0.0014˚C between the
lead and the board!
For this reason, the lead-frame of the LMP2014 is made of
copper. This results in equal and opposite junctions which
cancel this effect.
OVERLOAD RECOVERY
The LMP2014 recovers from input overload much faster
than most chopper-stabilized op amps. Recovery from driving the amplifier to 2X the full scale output, only requires
about 40 ms. Many chopper-stabilized amplifiers will take
from 250 ms to several seconds to recover from this same
overload. This is because large capacitors are used to store
the unadjusted offset voltage.
20132916
FIGURE 1.
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10
PRECISION STRAIN-GAUGE AMPLIFIER
This Strain-Gauge amplifier (Figure 4) provides high gain
(1006 or ~60 dB) with very low offset and drift. Using the
resistors’ tolerances as shown, the worst case CMRR will be
greater than 108 dB. The CMRR is directly related to the
resistor mismatch. The rejection of common-mode error, at
the output, is independent of the differential gain, which is
set by R3. The CMRR is further improved, if the resistor ratio
matching is improved, by specifying tighter-tolerance resistors, or by trimming.
(Continued)
20132917
FIGURE 2.
20132918
FIGURE 4.
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. These
configurations utilize the excellent DC performance of the
LMP2014 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 300 MHz of overall
GBW (AV = 100) while keeping the worst case output shift
due to VOS less than 4 mV. The LMP2014 output voltage is
kept at about mid-point of its overall supply voltage, and its
input common mode voltage range allows the V- terminal to
be grounded in one case (Figure 5, inverting operation) and
tied to a small non-critical negative bias in another (Figure 6,
non-inverting operation). 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.
20132904
FIGURE 3.
INPUT CURRENTS
The LMP2014’s input currents are 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 tend to
increase slightly when the common-mode voltage is near the
minus supply. (See the typical curves.) At high temperatures
such as 70˚C, the input currents become larger, 0.5 nA
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. A small resistance such as 1
kΩ can provide some protection against very large transients
or overloads, and will not increase the offset significantly.
11
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LMP2014MT
Application Information
LMP2014MT
Application Information
(Continued)
20132920
FIGURE 6.
20132919
It should be kept in mind that in order to minimize the output
noise voltage for a given closed-loop gain setting, one could
minimize the overall bandwidth. As can be seen from Equation 1 above, the output noise has a square-root relationship
to the Bandwidth.
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 "Tee"
network as feedback. See the LMC6442 data sheet (Application Notes section) for more details on this.
FIGURE 5.
TABLE 1. Composite Amplifier Measured Performance
AV
R1
Ω
R2
Ω
C2
pF
BW
MHz
SR en p-p
(V/µs) (mVPP)
50
200
10k
8
3.3
178
37
100
100
10k
10
2.5
174
70
100
1k
100k
0.67
3.1
170
70
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, en
p-p, for different closed-loop gain, AV, settings, where −3 dB
Bandwidth is BW:
20132921
FIGURE 7.
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LMP2014MT
Application Information
1/f corner frequency = 100 Hz
AV = 2000
(Continued)
LMP2014 AS ADC INPUT AMPLIFIER
Measurement time = 100 sec
Bandwidth = 2 Hz
The LMP2014 is a great choice for an amplifier stage immediately before the input of an ADC (Analog-to-Digital Converter), whether AC or DC coupled. See Figure 7 and Figure
8. This is 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 for 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 5 LSBs.
This example will result in about 2.2 mVPP (1.9 LSB) of
output noise contribution due to the op amp alone, compared to about 594 µVPP (less than 0.5 LSB) when that
op amp is replaced with the LMP2014 which has no 1/f
contribution. If the measurement time is increased from
100 seconds to 1 hour, the improvement realized by
using the LMP2014 would be a factor of about 4.8 times
(2.86 mVPP compared to 596 µV when LMP2014 is
used) mainly because the LMP2014 accuracy is not
compromised by increasing the observation time.
D) Copper leadframe construction minimizes any thermocouple effects which would degrade low level/high gain
data conversion application accuracy (see discussion
under "The Benefits of the LMP2014" section above).
E) Rail-to-Rail output swing maximizes the ADC dynamic
range in 5-Volt single-supply converter applications. Below are some typical block diagrams showing the
LMP2014 used as an ADC amplifier (Figure 7 and Figure
8).
B) Fast large-signal settling time to 0.01% of final value (1.4
µs) allows 12 bit accuracy at 100 KHZ 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 op amp performance, based
on a typical low-noise, high-performance commerciallyavailable device, for comparison:
Op amp flatband noise = 8nV/
20132922
FIGURE 8.
13
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LMP2014MT Quad High Precision, Rail-to-Rail Output Operational Amplifier
Physical Dimensions
inches (millimeters) unless otherwise noted
14-Pin TSSOP
NS Package Number MTC14
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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