NSC LMP8100MAX

LMP8100
Programmable Gain Amplifier
General Description
Features
The LMP8100 programmable gain amplifier features an adjustable gain from 1 to 16 V/V in 1 V/V increments. At the core
of the LMP8100 is a precision, 33 MHz, CMOS input, rail-torail input/output operational amplifier with a typical open-loop
gain of 110 dB. Amplifier closed-loop gain is set by an array
of precision thin-film resistors. Amplifier control modes are
programmed via a serial port that allows devices to be cascaded so that an array of LMP8100 amplifiers can be programmed by a single serial data stream. The control mode
registers are double buffered to insure glitch-free transitions
between programmed settings. The LMP8100 is part of the
LMP® precision amplifier family and is ideal for a variety of
applications.
Typical Values, TA = 25°C
■ Gain error (over temperature range)
0.03%
— LMP8100A
0.075%
— LMP8100
1 to 16 V/V in 1 V/V steps
■ Gain range
■ Programmable frequency compensation
■ Input zero calibration switch
250 μV
■ Input offset voltage (max, LMP8100A)
0.1 pA
■ Input bias current
12 nV/√Hz
■ Input noise voltage
33 MHz
■ Unity gain bandwidth
12 V/μs
■ Slew rate
20 mA
■ Output current
2.7V to 5.5V
■ Supply voltage range
5.3 mA
■ Supply current
+
−
Rail-to-Rail
output
swing
V
−50
mV
to
V
+50
mV
■
The amplifier features several programmable controls including: gain; a power-conserving shutdown mode which can
reduce current consumption to only 20 μA; an input zeroing
switch which allows the output offset voltage to be measured
to facilitate system calibration; and four levels of internal frequency compensation which can be set to maximize bandwidth at the different gain settings.
The LMP8100 comes in a 14-Pin SOIC package.
Applications
■
■
■
■
■
■
Industrial instrumentation
Data acquisition systems
Test equipment
Scaling amplifier
Gain control
Sensor interface
Simplified Block Diagram
20147607
LMP® is a registered trademark of National Semiconductor Corporation.
© 2008 National Semiconductor Corporation
201476
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LMP8100 Programmable Gain Amplifier
April 18, 2008
LMP8100
Block Diagram
20147602
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If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
ESD Tolerance (Note 2)
Human Body Model
Machine Model
VIN Differential
Output Short Circuit Duration (Note 3)
Supply Voltage (VS = V+ – V−)
Voltage at Input and Output Pins
Input Current
Storage Temperature Range
Junction Temperature (Note 4)
Operating Ratings
2 kV
200V
2.5V
235°C
260°C
(Note 1)
Supply Voltage (VS = V+ – V−)
Junction Temperature Range (Note 4)
LMP8100A
LMP8100
6V
V+ +0.3V, V− −0.3V
±10 mA
−65°C to +150°C
+150°C
2.7V to 5.5V
−40°C to +125°C
−40°C to +85°C
Package Thermal Resistance (θJA (Note 4)
14-Pin SOIC
145°C/W
5V Electrical Characteristics
Unless otherwise specified, all limits are guaranteed for TA = 25°C. V+ = 5V , V– = 0V, DGND = 0V, +IN = GRT = V+/2, RL = 10
kΩ to V+/2; Gain = 1 V/V. Boldface limits apply at the temperature extremes.
Symbol
Parameter
Gain Error
Gain Error
TCGE
VOS
Conditions
Min
(Note 6)
Typ
(Note 5)
Max
(Note 6)
LMP8100A
0V < +IN (DC) < 3.5V,
0.015
0.03
0.03
LMP8100
1 V/V ≤ Gain ≤ 16 V/V,
0.5V < VOUT < 4.5V
0.015
0.075
0.075
%
LMP8100 Gain Error (Gain = 1 V/V)
Extended +IN Range
+IN > 3.5V,
0.3V < VOUT < 4.7V
Gain Drift
LMP8100A
Gain = 16
0.5
2.2
LMP8100
Gain = 16
0.8
4.8
LMP8100A
±50
±250
±450
LMP8100
±50
±400
±600
1.5
5
µV/°C
0.1
5
100
pA
Input Offset Voltage
TCVOS
Input Offset Temp Coefficient
IB
Input Bias Current
en
Input-Referred Noise Voltage
0.1
0.2
Units
(Note 8)
f = 10 kHz, 1 V/V ≤ Gain ≤ 16 V/V
12
f = 0.1 Hz to 10 Hz, 1 V/V ≤ Gain
3.8
C1 = C0 = 0, Gain = 1 V/V
33
C1 = C0 = 0, Gain = 2 V/V
15.5
C1 = C0 = 1, Gain = 16 V/V
9.5
%
ppm/°C
µV
nV/
µVPP
≤ 16 V/V
BW
Bandwidth
SR
Slew Rate
(Note 7)
PSRR
Power Supply Rejection Ratio
2.7V < V+ < 5.5V
VO
Output Swing
High
+IN = 5V
Output Swing
Low
+IN = 0V
IO
Output Current
Sourcing and Sinking
VIN
Input Voltage Range
IS
Supply Current
MHz
12
90
85
100
4.9
4.85
4.95
50
15
dB
V
100
150
20
–0.2
0
5.3
3
V/µs
mV
mA
5.2
5.0
V
6.0
7.2
mA
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LMP8100
Soldering Information
Lead Temperature, Infrared or
Convection Reflow (20 sec)
Lead Temperature, Wave Solder (10
sec)
Absolute Maximum Ratings (Note 1)
LMP8100
Symbol
IPD
Parameter
Conditions
Min
(Note 6)
Supply Current, Power Down
Feedback Resistance
RIN
Input Impedance
f = 10 Hz
Typ
(Note 5)
Max
(Note 6)
3.5
20
40
Units
µA
5.6
kΩ
>10
GΩ
3.3V Electrical Characteristics
Unless otherwise specified, all limits are guaranteed for TA = 25°C. V+ = 3.3V , V– = 0V, DGND = 0V, +IN = GRT = V+/2,
RL = 10 kΩ to V+/2; Gain = 1 V/V. Boldface limits apply at the temperature extremes.
Symbol
Parameter
Gain Error
Gain Error
TCGE
VOS
Typ
(Note 5)
Max
(Note 6)
0V < +IN < 1.8V,
0.015
0.03
0.03
LMP8100
1 V/V ≤ Gain ≤ 16 V/V,
0.3V < VOUT < 3.0V
0.015
0.075
0.075
%
+IN > 1.8V,
0.3V < VOUT < 3.0V
Gain Drift
LMP8100A
Gain = 16
0.5
2.2
LMP8100
Gain = 16
0.8
4.8
LMP8100A
±50
±250
±450
LMP8100
±50
±400
±600
1.5
5
µV/°C
0.1
5
100
pA
Input Offset Voltage
Input Offset Temp Coefficient
Input Bias Current
en
Input-referred Noise Voltage
Bandwidth
0.1
0.2
Units
LMP8100 Gain Error (Gain = 1 V/V)
Extended +IN Range
IB
(Note 8)
f = 10 kHz, 1 V/V ≤ Gain ≤ 16 V/V
12
f = 0.1 Hz to 10 Hz, 1 V/V ≤ Gain ≤
16 V/V
3.8
C1 = C0 = 0, Gain = 1 V/V
33
C1 = C0 = 0, Gain = 2 V/V
15.5
C1 = C0 = 1, Gain = 16 V/V
9.5
SR
Slew Rate
(Note 7)
PSRR
Power Supply Rejection Ratio
2.7V < V+ < 3.6V
VO
Output Swing
High
+IN = 3.3V
Output Swing
Low
+IN = 0V
IO
Output Current
Sourcing and Sinking
VIN
Input Voltage Range
IS
Supply Current
IPD
Supply Current, Power Down
RIN
Min
(Note 6)
LMP8100A
TCVOS
BW
Conditions
100
3.2
3.15
3.25
50
15
µV
µVPP
MHz
V/µs
dB
V
100
150
20
−0.2
0
ppm/°C
nV/
12
90
80
%
mV
mA
3.5
3.3
V
5.1
5.8
7.0
mA
1.8
20
40
µA
Feedback Resistance
5.6
kΩ
Input Impedance
>10
GΩ
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Unless otherwise specified, all limits guaranteed for TA = 25°C, V+ - V− ≥ 2.7V, VD = V+ - DGND ≥ 2.5V.
Symbol
Parameter
Conditions
Min
(Note 6)
Typ
(Note 5)
Max
(Note 6)
Units
0.3 × VD
V
VIL
Logic Low Threshold
VIH
Logic High Threshold
ISDO
Output Source Current, SDO
VD = 3.3V or 5.0V,
CS = 0V, VOH = V+ – 0.7V
−7
Output Sink Current, SDO
VD = 3.3V or 5.0V,
CS = 0V, VOL = 1.0V
10
IOZ
Output Tri-state Leakage Current,
SDO
VD = 3.3V or 5.0V,
CS = VD = 3.3V or 5V
t1
High Period, SCK
(Note 9)
100
ns
t2
Low Period, SCK
(Note 9)
100
ns
t3
Set Up Time, CS to SCK
(Note 9)
50
ns
t4
Set Up Time, SDI to SCK
(Note 9)
30
ns
t5
Hold Time, SCK to SDI
(Note 9)
10
ns
t6
Prop. Delay, SCK to SDO
(Note 9)
t7
Hold Time, SCK Transition to CS
Rising Edge
(Note 9)
50
t8
CS Inactive
(Note 9)
50
t9
Prop. Delay, CS to SDO Active
(Note 9)
t10
Prop. Delay, CS to SDO Inactive
(Note 9)
t11
Hold Time, SCK Transition to CS
Falling Edge
(Note 9)
10
Signal Rise and Fall Times
(Note 9)
1.5
tR/tF
0.7 × VD
V
mA
±1
µA
60
ns
ns
ns
50
ns
50
ns
ns
5
ns
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 for which specific performance is not guaranteed. For guaranteed specifications and the test conditions, see Electrical Characteristics.
Note 2: Human Body Model, applicable std. MIL-STD-883, Method 3015.7. Machine Model, applicable std. JESD22–A115–A (ESD MM std. of JEDEC). FieldInduced Charge-Device Model, applicable std. JESD22–C101–C (ESD FICDM std. of JEDEC).
Note 3: The short circuit test is a momentary test which applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated
ambient temperature can exceed the maximum allowable junction temperature of 150°C.
Note 4: The maximum power dissipation is a function of TJ(MAX), θJA. The maximum allowable power dissipation at any ambient temperature is PD = (TJ(MAX) –
TA)/ θJA. All numbers apply for packages soldered directly onto a PC Board.
Note 5: Typical Values indicate the most likely parametric norm as determined at the time of characterization. Actual typical values may vary over time and will
also depend on the application and configuration. The typical values are not tested and are not guaranteed on shipped production material.
Note 6: All limits are guaranteed by testing or statistical analysis.
Note 7: Slew rate is the average of the rising and falling slew rates.
Note 8: The offset voltage average drift is determined by dividing the value of VOS at the temperature extremes by the total temperature change.
Note 9: Load for these tests is shown in the Timing Diagram Test Circuit.
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LMP8100
Electrical Characteristics (Serial Interface)
LMP8100
Connection Diagram
14-Pin SOIC
20147601
Top View
Ordering Information
Package
Part Number
LMP8100AMA
14-Pin SOIC
LMP8100AMAX
LMP8100MA
LMP8100MAX
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Package Marking
LMP8100AMA
Transport Media
2.5k units Tape and Reel
55 Units/Rail
LMP8100MA
2.5k units Tape and Reel
6
NSC Drawing
55 Units/Rail
M14A
LMP8100
Timing Diagram Test Circuit
20147653
Timing Diagram
20147603
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LMP8100
Test Circuit Diagram
20147609
Test Circuit
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LMP8100
Typical Performance Characteristics
Offset Voltage Distribution
Offset Voltage Distribution
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20147686
TCVOS Distribution
TCVOS Distribution
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20147684
VOS vs. VIN
VOS vs. VIN
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20147667
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LMP8100
VOS vs. VS
VOS vs. VS
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20147664
IB vs. VIN
IB vs. VIN
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20147663
IS vs. VS
IS vs. VS
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20147661
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LMP8100
DC Gain Error A = 1
DC Gain Error A = 1
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20147689
DC Gain Error A = 2
DC Gain Error A = 2
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20147690
Small Signal Gain Error vs. +IN DC Level
Small Signal Gain Error vs. +IN DC Level
20147651
20147633
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LMP8100
PSRR vs. Frequency
PSRR vs. Frequency
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20147610
IOUT vs. VOUT (Source)
IOUT vs. VOUT (Sink)
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20147668
IOUT vs. VOUT (Source)
IOUT vs. VOUT (Sink)
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LMP8100
Small Signal Step Response
Small Signal Step Response
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20147636
Small Signal Step Response
Small Signal Step Response
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20147637
Small Signal Step Response
Small Signal Step Response
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20147640
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LMP8100
Small Signal Step Response
Small Signal Step Response
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20147641
Large Signal Step Response
Large Signal Step Response
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20147644
Large Signal Step Response
Large Signal Step Response
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20147646
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LMP8100
Large Signal Step Response
Large Signal Step Response
20147648
20147647
Large Signal Step Response
Large Signal Step Response
20147650
20147649
THD+N vs. Frequency
THD+N vs. Frequency
20147674
20147675
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LMP8100
THD+N vs. VOUT
THD+N vs. VOUT
20147673
20147672
Bandwidth vs. Capacitive Load
Bandwidth vs. Capacitive Load
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20147618
Peaking vs. Capacitive Load
Peaking vs. Capacitive Load
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20147621
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LMP8100
Peaking vs. Capacitive Load
Gain vs. Frequency
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20147623
Gain vs. Frequency
Gain vs. Frequency
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20147628
Gain vs. Frequency
AC Gain Error vs. Frequency
20147656
20147627
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LMP8100
AC Gain Error vs. Frequency
AC Gain Error vs. Frequency
20147655
20147657
AC Gain Error vs. Frequency
AC Gain Error vs. Frequency
20147658
20147659
Noise vs. Frequency
0.1 Hz to 10 Hz Noise
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20147654
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LMP8100
Closed Loop Output Impedance vs. Frequency
Input Impedance
20147631
201476a1
SDO V vs. I
SDO V vs. I
20147634
20147652
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LMP8100
Applications Information
LIFETIME DRIFT
Offset voltage (VOS) and gain are electrical parameters which
may drift over time. This drift, known as lifetime drift, is very
common in operational amplifiers; however, its effect is more
evident in precision amplifiers. This is due to the very low offset voltage specification and very precise gain specification
of the LMP8100. The LMP8100 has an option to zero out the
offset voltage. When the zero bit of the register is set high,
+IN is connected to GRT. Output offset voltage can be measured and adjusted out of the signal path. See the “Input
Zeroing” section, for more information. Numerous reliability
tests have been performed to characterize this drift for the
LMP8100. Prior to each long term reliability test the input offset voltage and gain at 2X and 16X of each LMP8100 was
measured at room temperature.
The long term reliability tests include Operating Life Time
(OPL) performed at 150°C for an extended period of time and
Temperature Humidity Bias Testing (THBT) at 85°C and 85%
humidity for an extended period of time. The offset voltage
and gain of 2X and 16X were measured again at room temperature after each reliability test.
The offset voltage drift is the difference between the initial
measurement and the later measurement, after the reliability
test.
The gain drift is the percentage difference between the initial
measurement and the later measurement, after the reliability
test. Figure 1 – Figure 4 show the offset voltage drift and gain
drift after 1000 hours of OPL.
Figure 5 – Figure 8 show the offset voltage drift and gain drift
after 1000 hours of THBT.
20147692
FIGURE 2. OPL VOS Drift
20147693
FIGURE 3. OPL Gain Drift, A = 2
20147691
FIGURE 1. OPL VOS Drift
20147694
FIGURE 4. OPL Gain Drift, A = 16
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LMP8100
20147695
20147698
FIGURE 5. THBT VOS Drift
FIGURE 8. THBT Gain Drift, A = 16
POWER-ON RESET
The LMP8100 has a power-up reset feature that sets all the
register bits to 0 when the part is powered up. To implement
this feature the CS and SCK pins must be held at or above
VIH when the LMP8100 is powered-up. Failure to power up in
this method can lead to an unpredictable state of the register
bits after power-up.
CONTROL REGISTER
The control register retains the information which controls the
amplifier gain, bandwidth compensation, input zeroing, and
power down. The register is loaded by way of the serial control
interface. The register is double buffered so that changes can
be made with minimum effect on amplifier performance. Table
1 shows the organization of the control register. Table 2 gives
the codes for gain setting, input zeroing and power down control. Table 3 shows the codes for the four gain-bandwidth
compensation levels.
20147696
TABLE 1. Control Register Format
FIGURE 6. THBT VOS Drift
C1
C0
Zero
PD
MSB
G3
G2
G1
G0
LSB
C0, C1: Compensation setting
Zero: Zero Input
PD: Power Down
G0 to G3: Gain setting
20147697
FIGURE 7. THBT Gain Drift, A = 2
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LMP8100
TABLE 4. Amplifier Gain and Compensation
vs. Bandwidth
TABLE 2. Input Zero, Power-Down
and Gain Setting Codes
Zero
PD
G3
G2
G1
G0
Non-Inverting
Gain
0
0
0
0
0
1
V/V
dB
C1
C0
0
0
0
0
1
2
1
0
0
0
33.0
0
0
0
1
0
3
0
0
0
1
1
4
2
6.02
0
0
15.5
0
0
1
0
0
5
0
0
1
0
1
6
6
15.6
0
0
4.2
0
0
1
1
0
7
6
15.6
0
1
8.3
0
0
1
1
1
8
0
1
0
0
0
9
11
20.8
0
0
2.0
0
1
0
0
1
10
11
20.8
0
1
3.9
0
1
0
1
0
11
11
20.8
1
0
6.6
0
1
0
1
1
12
0
1
1
0
0
13
16
24.1
0
0
1.3
0
1
1
0
1
14
16
24.1
0
1
2.3
0
1
1
1
0
15
16
24.1
1
0
3.8
16
24.1
1
1
9.5
0
1
1
1
1
16
X
1
X
X
X
X
Power Down
1
0
X
X
X
X
Zero Input
Gain
C0
Compensation
Level
0
0
0
0
1
1
1
0
2
1
1
3
Condition
Maximum
Compensation
Minimum
Compensation
AMPLIFIER GAIN SETTING AND BANDWIDTH
COMPENSATION CONTROL
The gain of the LMP8100 is set to one of 16 levels under program control by setting the appropriate bits G[3:0] of the
control register with a number from 00h to 15h. This sets the
gain to a level from 1 V/V to 16 V/V respectively.
The gain-bandwidth compensation is also selectable to one
of four levels under program control. The amount of compensation can be decreased to maximize the available bandwidth
as the gain of the amplifier is increased. The compensation
level is selected by setting bits C[1:0] of the control register
with a number from 00b to 11b with 00b being maximum compensation and 11b being minimum compensation. Table 4
shows the bandwidths achieved at several gain and compensation settings. It will be noted that for gains between X1 and
X5, the recommended compensation setting is 00b. For gain
settings between X6 and X10, compensation settings may be
00b and 01b. Gain settings between X11 and X15 may use
the three bandwidth compensation settings between 00b and
10b. At a gain of X16, all bandwidth compensation ranges
may be used. Note that, for lower gains, it is possible to undercompensate the amplifier into instability.
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3 dB Bandwidth
(MHz)
NON-INVERTING AMPLIFIER OPERATION
The principal application of the LMP8100 is as a non-inverting
amplifier as shown in the simplified schematic, Figure 9. The
amplifier supply voltage (V+ to V−) is specified as 5.5V maximum. The V– supply pin is connected to the system ground
for single supply operation. V− can be returned to a negative
voltage when required by the application. The digital supply
voltage for the serial interface is applied between the V+ supply pin and DGND.
TABLE 3. Amplifier Gain Compensation Codes
C1
Compensation Bits
20147605
FIGURE 9. Basic Non-Inverting Amplifier
22
Any resistance between the GRT pins and either ground or a
reference voltage will change the gain to
20147676
FIGURE 11. GRT Connection Methods
The GRT pin can be connected to a reference voltage source
to provide an offset adjustment to the gain function. Any DC
resistance that may be present between the voltage source
and the GRT pin must be kept to an absolute minimum to
avoid introducing gain errors into the circuit.
INPUT ZEROING
Measurements made with the LMP8100 in the signal path
may be adjusted for the output offset voltage of the amplifier.
For example: The measurement of VOUT for offset correction
might be made using an ADC under microprocessor control.
Output offset is measured under program control by setting
the ZERO bit in the programming register. In this mode, +IN
is disconnected from the input pin and internally connected to
the GRT input. Figure 12 shows the LMP8100 in the input
zeroing mode.
20147679
FIGURE 10. LMP8100 with External Parasitical
Resistance
The connection between the GRT pins and ground or a reference voltage should be as short as possible using wide
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LMP8100
traces to minimize the parasitical resistance. Figure 11 shows
two suggested methods of connecting the GRT pins to a
ground plane on the same layer or to a ground plane on a
different layer of the PCB.
GRT PINS
The GRT pins must have a low impedance connection to either ground or a reference voltage. Any parasitical impedance
on these pins will affect the gain accuracy of the LMP8100.
Figure 10 shows a simplified schematic of the LMP8100
showing the internal gain resistors and an external parasitical
resistance RP. The gain of the LMP8100 is determined by
RF and RG, the values of which are set by the internal register.
The gain of the amplifier is given by the equation
LMP8100
20147606
FIGURE 12. Non-Inverting Input Zeroing Function
The serial clock, SCK controls the serial loading process. All
eight data bits are required to correctly program the amplifier.
The falling edge of CS enables the shift register to receive
data. The SCK signal must be high during the falling and rising
edge of CS. Each data bit is clocked into the shift register on
the rising edge of SCK. Data is transferred from the shift register to the holding register on the rising edge of CS. Operation
is shown in the timing diagram,Figure 13.
SERIAL CONTROL INTERFACE OPERATION
The LMP8100 gain, bandwidth compensation, power down,
and input zeroing are controlled by data stored in a programming register. Data to be written into the control register is first
loaded into the LMP8100 via the serial interface. The serial
interface employs an 8-bit shift register. Data is loaded
through the serial data input, SDI. Data passing through the
shift register is output through the serial data output, SDO.
20147624
FIGURE 13. Serial Control Interface Timing
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shown in Figure 14. After the microcontroller writes a byte all
registers will have the same value.
Star Configuration
This configuration can be used if each LMP8100 will always
have the same value in each register. The connections are
20147680
FIGURE 14. Star Configuration
Daisy Chain Configuration
lowing LMP8100. The following two examples show how the
registers are written.
This configuration can be used to program the same or different values in the register of each LMP8100. The connections are shown in Figure 15. In this configuration the SDO
pin of each LMP8100 is connected to the SDI pin of the folIf all three LMP8100s need a gain of 11 with a compensation level of 10. (10001010)
Register of
LMP8100 #1
Register of
LMP8100 #2
Register of
LMP8100 #3
Notes
Power on
00000000
00000000
00000000
Default power on state (see above)
Byte one sent
10001010
00000000
00000000
Byte two sent
10001010
10001010
00000000
Byte three sent
10001010
10001010
10001010
The data in the register of LMP8100 #1 is
shifted into the register of LMP8100 #2, the
data in the register of LMP8100 #2 is shifted
into the register of LMP8100 #3.
If LMP8100 #1 needs a gain of 11 with a compensation level of 10 (10001010), LMP8100 #2 needs a gain of 6 with a compensation
of 00 (00000101), and LMP8100 #3 needs a gain of 2 with a compensation of 00 (00000001).
Register of
LMP8100 #1
Register of
LMP8100 #2
Register of
LMP8100 #3
Notes
Power on
00000000
00000000
00000000
Default power on state (see above)
Byte one sent
00000001
00000000
00000000
Byte two sent
00000101
00000001
00000000
Byte three sent
10001010
00000101
00000001
The data in the register of LMP8100 #1 is
shifted into the register of LMP8100 #2, the
data in the register of LMP8100 #2 is shifted
into the register of LMP8100 #3.
25
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LMP8100
The serial control pins can be connected in one of two ways
when two or more LMP8100s are used in an application.
LMP8100
20147681
FIGURE 15. Daisy Chain Configuration
POWER SUPPLY PURITY AND BYPASSING
Particular attention to power supply purity is needed in order
to preserve the LMP8100's gain accuracy and low noise. The
LMP8100 worst-case PSRR is 85 dB or 56.2 µV/V. Nevertheless, the usable dynamic range, gain accuracy and inherent low noise of the amplifier can be compromised through
the introduction and amplification of power supply noise.
To decouple the LMP8100 from supply line AC noise, a 0.1
µF capacitor should be located on each supply line, close to
the LMP8100. Adding a 10 µF capacitor in parallel with the
0.1 µF capacitor will reduce the noise introduced to the
LMP8100 even more by providing an AC path to ground for
most frequency ranges.
A power supply dropout (V+ -V− < 2.7V) can cause an unintended reset of the register. If a dropout occurs, the register
will need to be reprogrammed with the correct values.
SCALING AMPLIFIER
The LMP8100 is ideally suited for use as an amplifier between
a sensor that has a wide output range and an ADC. As the
signal from the sensor changes the gain of the LMP8100 can
be changed so that the entire input range of the ADC is being
used at all times. Figure 16 shows a data acquisition system
using the LMP8100 and the ADC121S101. The 100Ω resistor
and 390 pF capacitor form an antialiasing filter for the ADC121S101. The capacitor also stores and delivers charge to
the switched capacitor input of the ADC. The capacitive load
on the LMP8100 created by the 390pF capacitor is decreased
by the 100Ω resistor.
20147682
FIGURE 16. Data Acquisition System Using the LMP8100
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26
Make the traces between the Magnetic Field Sensor and
the LMP8100s short to minimize noise pickup.
• Place 0.1 μF capacitors close to each of the LMP8100
supply pins.
The following can be done to simplify the design:
• Connect the SCL, SCK, and CS lines in parallel and one
microcontroller can be used to drive both LMP8100s.
• The SDO pin can be left floating.
The LM317 and LM6171 are used for the supply of the Magnetic Sensor. The 100Ω potentiometer is used to adjust the
supply voltage to the Magnetic Field Sensor. The 2 kΩ potentiometer is used to fine tune the negative supply to set the
Magnetic Field Sensor output to zero.
20147625
FIGURE 17. Bridge Amplifier
27
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LMP8100
•
BRIDGE AMPLIFIER
In Figure 17 two LMP8100s are used with a LMP7711 to build
an amplifier for the signal from a GMR Magnetic Field Sensor.
The advantage of using the LMP8100 is that as the signal
strength from the Magnetic Field Sensor decreases, the gain
of the LMP8100 can be increased. An example is if the signal
from this composite amplifier is used to drive an ADC. When
the maximum magnetic field to be measured is applied, the
gain of the LMP7711 can be set to supply a full range signal
to the ADC input with the gain of the LMP8100 set to one. As
the magnetic field decreases, the gain of the LMP8100 can
be increased, so that the signal supplied to the ADC uses a
maximum amount of the ADC input range.
The following can be done to maximize performance:
• Connect the GRT pins directly together and to GND with
a low impedance trace.
LMP8100
Physical Dimensions inches (millimeters) unless otherwise noted
14-Pin SOIC
NS Package Number M14A
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28
LMP8100
Notes
29
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LMP8100 Programmable Gain Amplifier
Notes
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