NSC LF400CH

General Description
Applications
The LF400 is a fast-settling (under 400 ns to 001% for a
10V output step) Bi-FET operational amplifier Features include 16 MHz bandwidth 60Vms inverting slew rate low
input offset voltage (05 mV for the LF400A at 25 C) and
adjustable output current limit enabling the amplifier to drive
600X loads
Y
Typical Connection
Connection Diagram
Y
Y
Y
Y
Y
June 1989
DAC output amplifiers
High speed ramp generators
Fast buffers
Sample-and-holds
Fast integrators
Piezoelectric transducer signal conditioners
TLH9414–1
Note Pin 4 connected to case
TLH9414–2
Top View
Order Number LF400ACH LF400CH
LF400AMH or LF400MH
See NS Package Number H08B
Simplified Schematic
TLH9414–3
BI-FETTM is a trademark of National Semiconductor Corporation
C1995 National Semiconductor Corporation
TLH9414
RRD-B30M115Printed in U S A
LF400ALF400 Fast-Settling JFET-Input Operational Amplifier
LF400ALF400
Fast-Settling JFET-Input Operational Amplifier
Absolute Maximum Ratings (Notes 1 2)
If MilitaryAerospace specified devices are required
please contact the National Semiconductor Sales
OfficeDistributors for availability and specifications
g 18V
Supply Voltage
Temperature Range
LF400AMH LF400MH
LF400ACH LF400CH
Positive Supply Voltage
a 10V to a 16V
g 32V
Negative Supply Voltage
b 10V to b 16V
Differential Input Voltage
ESD Susceptibility (Note 9)
TMIN s TA s TMAX
b 55 C s TA s a 125 C
0 C s TA s a 70 C
g 16V
Continuous
Input Voltage Range (Note 3)
Output Short Circuit Duration (Pin 6)
Power Dissipation (Note 4) H package
Junction Temperature (TJMAX)
Storage Temperature
Lead Temperature (Soldering 10 sec)
Operating Ratings (Notes 1 2)
500 mW
150 C
b 65 C to a 150 C
a 300 C
800V
AC Electrical Characteristics (LF400ACH LF400CH)
The following specifications apply for V a e a 15V and Vb e b15V unless otherwise specified
Tested Limits in Boldface apply for TJ e 25 C to 95 C Design Limits in Boldface apply for TA e TMIN to
TMAX other Design Limits are for TA e 25 C all other limits for TJ e 25 C
LF400ACH
Symbol
Parameter
Conditions
LF400CH
Typical
(Note 6)
Tested Design
Tested Design
Typical
Limit
Limit
Limit
Limit
(Note 6)
(Note 7) (Note 8)
(Note 7) (Note 8)
Units
365
200
ns
ns
ts
Settling Time to 001%
to 010%
See Figure 1
See Figure 1
365
200
GBW
Minimum Gain
Bandwidth Product
AV e a 1 CL e 10 pF
16
14
16
14
MHz
SR
Minimum Slew Rate
Av e a 1 CL e 10 pF
30
27
30
27
Vms
AV e b1 CL e 10 pF
60
60
Vms
w
Phase Margin
AV e a 1 CL e 10 pF
60
60
Degrees
en
Input Noise Voltage
f e 1 kHz RS e 100X
Broadband RS e 100X
10 Hz to 10 kHz
23
23
23
23
nV0Hz
mV rms
in
Input Noise Current
f e 1 kHz
Broadband
10 Hz to 10 kHz
001
10
001
10
pA0Hz
pA rms
THD
Total Harmonic Distortion f e 1 kHz AV e b1
RL e 10k
0002
0002
%
CIN
Input Capacitance
7
7
pF
2
DC Electrical Characteristics (LF400ACH LF400CH)
The following specifications apply for V a e a 15V and Vb e b15V unless otherwise specified
Tested Limits in Boldface apply for TJ e 25 C to 95 C Design Limits in Boldface apply for TA e TMIN to
TMAX other Design Limits are for TA e 25 C all other limits for TJ e 25 C
LF400ACH
Symbol
VOS
IOS
Parameter
Maximum Input Offset Voltage
Maximum Input Offset Current
Conditions
Typical
(Note 6)
LF400CH
Tested Design
Tested Design Units
Typical
Limit
Limit
Limit
Limit
(Note 6)
(Note 7) (Note 8)
(Note 7) (Note 8)
VCM e 0V
TJ e 25 C
g 05
g 30
mV
RS e 0
RL e %
TJ e 70 C
g 20
g 50
mV
g 100
g 25
pA
nA
200
26
pA
nA
VCM e 0V (Note 5)
g 50
g 100
g 50
g 25
VCM e 0V (Note 5)
IB
Maximum Input Bias Current
RIN
Input Resistance
VCM
Input Common-Mode Voltage
Range
AVOL
Minimum Large Using Pin 6
Signal Voltage Using Pin 8
Gain
Minimum Output Using Pin 6
Voltage Swing Using Pin 8
Output
Short Circuit
Current
Pulse Test
VO
ISC
RO
Output
Resistance
200
26
1011
100
X
1011
b 12 to
a 14
g 11
b 12 to
a 14
g 11
V
VO e g 10V RL e 2 kX
300
100
300
100
VmV
VO e g 10V RL e 600X
280
100
280
100
VmV
RL e 2 kX
g 125
g 120
g 125
g 120
V
RL e 600X
g 120
g 110
g 120
g 110
V
15
45
100
mA
mA
mA
mA
25
MIN Using Pin 6
MAX Using Pin 6
MIN Using Pin 8
25
15
45
100
Using Pin 6
Open Loop DC
75
75
X
Using Pin 8
Open Loop DC
50
50
X
CMRR Minimum DC Common Mode
Rejection Ratio
b 11V s VIN s a 11V
PSRR
Minimum DC Power Supply
Rejection Ratio
Maximum Supply Current
IS
100
100
90
100
80
dB
a 10V s V a s a 15V
b 15V s V b s b 10V
VCM e 0V
100
90
100
80
dB
VO e 0V RL e %
110
130
110
130
mA
3
AC Electrical Characteristics (LF400AMH LF400MH)
The following specifications apply for V a e a 15V Vb e b15V and TJ e 25 C unless otherwise specified
Tested Limits in Boldface apply for TJ e b55 C to a 125 C
LF400AMH
Symbol
Parameter
Conditions
LF400MH
Typical
(Note 6)
Tested Design
Tested Design
Typical
Limit
Limit
Limit
Limit
(Note 6)
(Note 7) (Note 8)
(Note 7) (Note 8)
Units
365
200
ns
ns
ts
Settling Time to 001%
to 010%
See Figure 1
See Figure 1
365
200
GBW
Minimum Gain
Bandwidth Product
AV e a 1 CL e 10 pF
16
14
10
SR
Minimum Slew Rate
AV e a 1 CL e 10 pF
30
27
AV e b1 CL e 10 pF
60
60
Vms
16
14
10
MHz
MHz
30
27
Vms
w
Phase Margin
AV e a 1 CL e 10 pF
60
60
Degrees
en
Input Noise Voltage
f e 1 kHz RS e 100X
Broadband RS e 100X
10 Hz to 10 kHz
23
23
23
23
nV0Hz
mV rms
in
Input Noise Current
f e 1 kHz
Broadband
10 Hz to 10 kHz
001
10
001
10
pA0Hz
pA rms
THD
Total Harmonic Distortion f e 1 kHz AV e b1
RL e 10k
0002
0002
%
CIN
Input Capacitance
7
7
pF
DC Electrical Characteristics (LF400AMH LF400MH)
The following specifications apply for V a e a 15V Vb e b15V and TJ e 25 C unless otherwise specified
Tested Limits in Boldface apply for TJ e b55 C to a 125 C
LF400AMH
Symbol
VOS
Parameter
Maximum Input
Offset Voltage
Conditions
VCM e 0V
RS e 0
RL e %
TJ e 25 C
Maximum Input
Offset Current
VCM e 0V (Note 5)
IB
Maximum Input
Bias Current
VCM e 0V (Note 5)
RIN
Input Resistance
IOS
Typical
(Note 6)
g 50
LF400MH
Tested Design
Tested Design Unit
Typical
Limit
Limit
Limit
Limit
(Note 6)
(Note 7) (Note 8)
(Note 7) (Note 8)
g 05
g 30
mV
g 20
g 50
mV
g 100
g 25
pA
nA
200
50
pA
nA
g 100
g 50
g 15
VCM
Input Common-Mode
Voltage Range
AVOL
Minimum Large Using Pin 6 VO e g 10V RL e 2 kX
Signal Voltage Using Pin 8 V e g 10V R e 600X
O
L
Gain
100
4
200
35
100
X
1011
1011
b 12 to
a 14
g 11
b 12 to
a 14
g 11
V
300
100
300
50
VmV
280
100
280
50
VmV
DC Electrical Characteristics (LF400AMH LF400MH)
The following specifications apply for V a e a 15V Vb e b15V and TJ e 25 C unless otherwise specified
Tested Limits in Boldface apply for TJ e b55 C to a 125 C (Continued)
LF400AMH
Symbol
VO
Parameter
Minimum Output Using Pin 6
Voltage Swing
Using Pin 8
ISC
RO
Output
Short Circuit
Current
Output
Resistance
Conditions
Typical
(Note 6)
RL e 2 kX
LF400MH
Tested Design
Tested Design Units
Typical
Limit
Limit
Limit
Limit
(Note 6)
(Note 7) (Note 8)
(Note 7) (Note 8)
g 120
RL e 600X
Pulse Test
g 120
g 125
g 115
g 125
g 115
V
V
g 120
g 110
g 120
g 110
V
15
45
100
mA
mA
mA
mA
25
MIN Using Pin 6
MAX Using Pin 6
MIN Using Pin 8
25
15
45
100
Using Pin 6
Open Loop DC
75
75
X
Using Pin 8
Open Loop DC
50
50
X
CMRR Minimum DC Common Mode
Rejection Ratio
b 11V s VIN s a 11V
100
90
80
100
80
75
dB
dB
PSRR
Minimum DC Power Supply
Rejection Ratio
a 10V s V a s a 15V
b 15V s V b s b 10V
VCM e 0V
100
90
85
100
80
75
dB
dB
IS
Maximum Supply Current
VO e 0V RL e %
110
130
130
110
130
150
mA
mA
Note 1 Absolute Maximum Ratings indicate limits beyond which damage to the device may occur DC and AC electrical specifications do not apply when operating
the device beyond its specified operating conditions
Note 2 All voltages are with respect to ground
Note 3 Unless otherwise specified the Absolute Minimum Input Voltage is equal to the negative power supply voltage
Note 4 The maximum power dissipation must be derated at elevated temperatures as is dictated by TJMAX iJA and the ambient temperature TA iJA for the
LF400H is 150 CW in free air so a heat sink will generally be required when TA is greater than about 70 C iJC for the LF400H is 17 CW which dictates the use
of a heat sink with iCA less than about 35 CW when TA e a 125 C
Note 5 The input bias currents are junction leakage currents which approximately double for every 10 C increase in the junction temperature TJ Due to limited
production test time input bias currents are measured at TJ e 25 C In normal operation the junction temperature rises above the ambient temperature as a result
of internal power dissipation PD Use of a heat sink is recommended when input bias current must be minimized
Note 6 Typicals represent the most likely parametric norm
Note 7 Guaranteed to National’s AOQL (Average Outgoing Quality Level)
Note 8 Guaranteed but not 100% production tested These limits are not used to calculate outgoing quality levels
Note 9 Human body model 100 pF discharged through a 1500X resistor
5
Typical Performance Characteristics
Inverter Settling Time
Bode Plot
Gain Bandwidth
vs Temperature
Slew Rate vs Temperature
Undistorted Output
Voltage Swing
Undistorted Output
Voltage Swing
Distortion vs Frequency
Distortion vs Frequency
Equivalent Input
Noise Voltage
AC Common-Mode
Rejection
AC Power Supply Rejection
Common-Mode Input
Voltage Range
TLH9414–10
6
Typical Performance Characteristics
Output Voltage Swing
vs Supply Voltage
(Continued)
DC Gain vs Supply Voltage
Input Bias Current
vs Temperature
Power Supply Current vs
Power Supply Voltage
TLH9414–11
Settling TimePositive Output Swing
Settling TimeNegative Output Swing
TLH9414–12
TLH9414–13
Step Response
TLH9414–14
7
Typical Performance Characteristics
(Continued)
Step Response
Voltage Transfer Characteristic
TLH9414–15
TLH9414–16
Voltage Transfer Characteristic
TLH9414–17
TLH9414–18
8
Typical Performance Characteristics
(Continued)
CommonMode Voltage Transfer Characteristic
TLH9414–19
TLH9414–20
Application Hints
input capacitance Since input capacitance is made up of
several stray capacitances that are difficult to predict the
compensation capacitor will generally have to be determined empirically for best settling time A good starting
point is around 10 pF for AV e b1
Settling time may be verified using a circuit similar to the
one in Figure 1 The LF400 is connected for inverting operation and the output voltage is summed with the input voltage step When the LF400’s output voltage is equal to the
input voltage the voltage on the gate of Q1 will be zero Any
voltage appearing at this point will represent an error The
FET source follower output is observed on an oscilloscope
and the settling time is equal to the time required for the
error signal displayed on the oscilloscope to decay to less
than one-half the necessary accuracy (see oscilloscope
photos of ‘‘Settling TimePositive Output Swing’’ and ‘‘Settling TimeNegative Output Swing’’) For a 10V input signal settling time to 001% (1 mV) will occur when the displayed error is less than mV Since settling time is strongly dependent on slew rate settling will be faster for smaller
signal swings The LF400’s inverting slew rate is faster than
its non-inverting slew rate so settling will be faster for inverting applications as well
It is important to note that the oscilloscope input amplifier
will be overdriven during a settling time measurement so
the oscilloscope must be capable of recovering from overdrive very quickly Very few oscilloscopes are suitable for
this sort of measurement The signal generator used for set-
The LF400 is a high-speed low input bias current Bi-FET
operational amplifier capable of settling to 001% of a 10V
output swing in less than 400 ns The rugged JFET inputs
allow differential input voltages as high as 32V without a
large increase in input current However the inputs should
never be driven to voltages lower than the negative supply
as this can result in input currents large enough to damage
the device To prevent this from occurring when power is
first applied always turn the positive and negative power
supplies on simultaneously or turn the negative supply on
first
Exceeding the common-mode input range will not damage
the device as long as the Absolute Maximum Ratings are
not violated but it will result in a high output voltage Latching will not occur however and when the offending signal is
removed the LF400 will recover quickly
The nominal power supply voltage is g 15V but the LF400
will operate satisfactorily from g 10V to g 16V The LF400 is
functional down to g 5V but performance will be degraded
(See Typical Performance curves)
Settling Time Considerations
The settling performance of any high-speed operational amplifier is highly dependent on the external components and
circuit board layout Capacitance between the amplifier
summing junction and ground affects the closed-loop transfer function and should be minimized The compensation
capacitor CC between the output and the inverting input
should be carefully chosen to counteract the effect of the
9
Application Hints (Continued)
CL s 49 pF
TLH9414–21
FIGURE 1 Simplified Settling Time Test Circuit (see Text)
tling time testing must be able to drive 50X with a very clean
g 5V square wave For more information on measuring settling time see Application Note AN-428
Output Drive and Current Limit
The LF400 can drive heavier resistive loads than most operational amplifiers The output at pin 6 is internally currentlimited when the voltage drop across the 25X output resistor reaches about 055V (IOUT e 22 mA) When more output current is needed pin 8 provides a means of increasing
the maximum output current up to about 100 mA A resistor
may be connected from pin 8 to pin 6 paralleling the internal sense resistor and increasing the current limit threshold
(Figure 3 ) Pins 6 and 8 may be shorted together to completely bypass the current limiting circuit To avoid damaging
the LF400 observe the power dissipation limitations mentioned in the Absolute Maximum Ratings and in Note 4
The effective load impedance (including feedback resistance) should be kept above 500X for fastest settling Load
capacitance should also be minimized if good settling time
is to be optimized Large feedback resistors will make the
circuit more susceptible to stray capacitance so in highspeed applications keep the feedback resistors in the 1 kX
to 2 kX range wherever practical Avoid the use of inductive
feedback resistors (some wirewounds for example) as these
will degrade settling time
Output Compensation
When operating at very low temperatures a compensation
network should be added to the LF400’s output The 100X
22 pF network shown on the first page of this data sheet
should be used when the junction temperature might reach
25 C (roughly 0 C ambient when the LF400 is ‘‘warmed
up’’) In applications where the device will be operating with
a junction temperature near 0 C the output RLC network in
Figure 1 should be used This network will provide a small
(about 20 ns) improvement in settling time at higher temperatures as well
Supply Bypassing
Power supply bypassing is extremely important for good
high-speed performance Ideally multiple bypass capacitors
as in Figure 2 should be used A 10 mF tantalum a 22 mF
ceramic and a 047 mF ceramic work well All bypass capacitor leads should be very short For best results the
ground leads of the capacitors should be separated to reduce the inductance to ground A ground plane layout approach will give the best results For simplicity bypass capacitors have been omitted from some of the schematics in
this data sheet but they should always be used
ILimit 055V
Rx25X
TLH9414–23
FIGURE 3 Increasing the current limit using pin 8
Current limit is now determined by RX in parallel with
the internal 25X sense resistor
Vos Adjustment
Offset voltage can be nulled using a 27k resistor and a 10k
potentiometer connected to pins 1 and 5 as shown in Figure
4a Bypassing the Vos adjust pins with 01 mF capacitors will
help to avoid noise pickup When not used for offset adjustment pins 1 and 5 can often be left open but to minimize
the possibility of noise pickup the unused Vos trim pins
should be connected to ground or V b
TLH9414–22
FIGURE 2 Power Supply Bypassing (see Text)
10
Application Hints (Continued)
In very critical applications where a manual adjustment is
impractical the LMC669 Auto Zero circuit may be used to
reduce the effective input offset voltage to around 5 mV as
in Figure 4b The LF400 will perform better than slower amplifiers in an auto zero loop because its fast settling capability keeps its summing node voltage more stable Therefore
the LMC669 is able to more accurately sample the summing
node voltage before making an offset correction
Input Bias Current
The JFET input stage of the LF400 ensures low input bias
current (200 pA maximum) when the die is at room temperature but this current approximately doubles for every 10 C
increase in temperature In applications that demand the
lowest possible input bias current a heat sink should be
used with the LF400 ‘‘Press on’’ heat sinks from manufacturers such as Thermalloy and AAVID can reduce junction
temperature by roughly 10 C to 40 C
TLH9414–24
FIGURE 4a Vos Adjust Circuit
Typical Applications
High-Speed DAC with Voltage Output
TLH9414–26
TLH9414–25
FIGURE 4b Automatic Offset
Adjustment Using LMC669
11
LF400ALF400 Fast-Settling JFET-Input Operational Amplifier
Physical Dimensions inches (millimeters)
Lit 106144
Order Number LF400ACH LF400CH LF400AMH or LF400MH
NS Package Number H08B
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