ETC LM6161J

LM6161/LM6261/LM6361
High Speed Operational Amplifier
General Description
Features
The LM6161 family of high-speed amplifiers exhibits an excellent speed-power product in delivering 300 V/ms and
50 MHz unity gain stability with only 5 mA of supply current.
Further power savings and application convenience are
possible by taking advantage of the wide dynamic range in
operating supply voltage which extends all the way down to
a 5V.
These amplifiers are built with National’s VIPTM (Vertically
Integrated PNP) process which provides fast PNP transistors that are true complements to the already fast NPN devices. This advanced junction-isolated process delivers high
speed performance without the need for complex and expensive dielectric isolation.
Y
Y
Y
Y
Y
Y
Y
Y
Y
High slew rate
High unity gain freq
Low supply current
Fast settling
Low differential gain
Low differential phase
Wide supply range
Stable with unlimited capacitive load
Well behaved; easy to apply
300 V/ms
50 MHz
5 mA
120 ns to 0.1%
k 0.1%
0.1§
4.75V to 32V
Applications
Y
Y
Y
Y
Y
Video amplifier
High-frequency filter
Wide-bandwidth signal conditioning
Radar
Sonar
Connection Diagrams
20-Lead LCC
10-Lead Flatpak
TL/H/9057–13
See NS Package Number W10A
TL/H/9057 – 14
See NS Package Number E20A
TL/H/9057 – 5
Temperature Range
NSC
Drawing
Commercial
0§ C s TA s a 70§ C
Package
b 25§ C s TA s a 85§ C
LM6261N
LM6361N
8-Pin
Molded DIP
N08E
LM6361J
8-Pin
Ceramic DIP
J08A
LM6361M
8-Pin Molded
Surface Mt.
M08A
LM6161E/883
5962-89621012A
20-Lead
LCC
E20A
LM6161W/883
5962-8962101HA
10-Pin
Ceramic Flatpak
W10A
Military
b 55§ C s TA s a 125§ C
Industrial
LM6161J/883
5962-8962101PA
LM6261M
See NS Package Number J08A,
N08E or M08A
VIPTM is a trademark of National Semiconductor Corporation.
C1995 National Semiconductor Corporation
TL/H/9057
RRD-B30M115/Printed in U. S. A.
LM6161/LM6261/LM6361 High Speed Operational Amplifier
September 1995
Absolute Maximum Ratings
(Note 12)
See AN-450 ‘‘Surface Mounting Methods and Their Effect
on Product Reliability’’ for other methods of soldering surface mount devices.
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Supply Voltage (V a b Vb)
Storage Temp Range
36V
g 8V
Differential Input Voltage (Note 8)
Common-Mode Voltage Range
(Note 10)
(V a b 0.7V) to (Vb a 0.7V)
Output Short Circuit to GND (Note 1)
Continuous
Soldering Information
Dual-In-Line Package (N, J)
Soldering (10 sec.)
260§ C
Small Outline Package (M)
Vapor Phase (60 sec.)
215§ C
Infrared (15 sec.)
220§ C
b 65§ C to a 150§ C
Max Junction Temperature
ESD Tolerance (Notes 6 and 7)
150§ C
g 700V
Operating Ratings (Note 12)
Temperature Range (Note 2)
LM6161
LM6261
LM6361
b 55§ C s TJ s a 125§ C
b 25§ C s TJ s a 85§ C
0§ C s TJ s a 70§ C
Supply Voltage Range
4.75V to 32V
DC Electrical Characteristics
The following specifications apply for Supply Voltage e g 15V, VCM e 0, RL t 100 kX and RS e 50X unless otherwise noted.
Boldface limits apply for TJ e TMIN to TMAX; all other limits TJ e 25§ C.
Symbol
Parameter
Conditions
Typ
VOS
Input Offset Voltage
VOS
Drift
Input Offset Voltage
Average Drift
Ib
Input Bias Current
IOS
Input Offset Current
IOS
Drift
Input Offset Current
Average Drift
RIN
Input Resistance
Differential
CIN
Input Capacitance
AV e a 1
AVOL
Large Signal
Voltage Gain
VOUT e g 10V,
RL e 2 kX (Note 9)
750
RL e 10 kX (Note 9)
2900
VCM
Input Common-Mode
Voltage Range
5
LM6161
LM6261
LM6361
Limit
(Notes 3, 11)
Limit
(Note 3)
Limit
(Note 3)
Units
7
10
7
9
20
22
mV
Max
10
@
10 MHz
Supply e a 5V
(Note 4)
Common-Mode
Rejection Ratio
b 10V s VCM s a 10V
PSRR
Power Supply
Rejection Ratio
g 10V s V g s g 16V
VO
Output Voltage
Swing
Supply e g 15V
and RL e 2 kX
2
3
6
3
5
5
6
mA
Max
150
350
800
350
600
1500
1900
nA
Max
0.4
nA/§ C
325
kX
1.5
Supply e g 15V
CMRR
mV/§ C
550
400
400
350
V/V
Min
a 14.0
a 13.9
a 13.8
a 13.9
a 13.8
a 13.8
a 13.7
Volts
Min
b 13.2
b 12.9
b 12.7
b 12.9
b 12.7
b 12.8
b 12.7
Volts
Min
4.0
3.9
3.8
3.9
3.8
3.8
3.7
Volts
Min
1.8
2.0
2.2
2.0
2.2
2.1
2.2
Volts
Max
94
80
74
80
76
72
70
dB
Min
90
80
74
80
76
72
70
dB
Min
a 14.2
a 13.5
a 13.3
a 13.5
a 13.3
a 13.4
a 13.3
Volts
Min
b 13.0
b 12.7
b 13.0
b 12.8
b 12.9
b 12.8
Volts
Min
b 13.4
2
pF
550
300
V/V
DC Electrical Characteristics (Continued)
The following specifications apply for Supply Voltage e g 15V, VCM e 0, RL t 100 kX and RS e 50X unless otherwise noted.
Boldface limits apply for TJ e TMIN to TMAX; all other limits TJ e 25§ C.
Symbol
Parameter
Conditions
VO (Continued)
Output Voltage
Swing (Continued)
Supply e a 5V
and RL e 2 kX
(Note 4)
Output Short
Circuit Current
Source
Sink
IS
LM6161
LM6261
LM6361
Limit
(Notes 3, 11)
Limit
(Note 3)
Limit
(Note 3)
Units
4.2
3.5
3.3
3.5
3.3
3.4
3.3
Volts
Min
1.3
1.7
2.0
1.7
1.9
1.8
1.9
Volts
Max
65
30
20
30
25
30
25
mA
Min
65
30
20
30
25
30
25
mA
Min
5.0
6.5
6.8
6.5
6.7
6.8
6.9
mA
Max
Typ
Supply Current
AC Electrical Characteristics
The following specifications apply for Supply Voltage e g 15V, VCM e 0, RL t 100 kX and RS e 50X unless otherwise noted.
Boldface limits apply for TJ e TMIN to TMAX; all other limits TJ e 25§ C.
Symbol
Parameter
GBW
Gain-Bandwidth
Product
SR
Slew Rate
PBW
Power Bandwidth
tS
Settling Time
Conditions
@
Typ
f e 20 MHz
50
LM6161
LM6261
LM6361
Limit
(Notes 3, 11)
Limit
(Note 3)
Limit
(Note 3)
Units
40
30
40
35
35
32
MHz
Min
200
180
200
180
200
180
V/ms
Min
Supply e g 5V
35
AV e a 1 (Note 8)
300
MHz
Supply e g 5V (Note 8)
200
V/ms
VOUT e 20 VPP
4.5
MHz
10V Step to 0.1%
AV e b1, RL e 2 kX
120
ns
45
Deg
wm
Phase Margin
AD
Differential Gain
NTSC, AV e a 4
k 0.1
%
wD
Differential Phase
NTSC, AV e a 4
0.1
Deg
enp-p
Input Noise Voltage
f e 10 kHz
15
nV/0Hz
inp-p
Input Noise Current
f e 10 kHz
1.5
pA/0Hz
Note 1: Continuous short-circuit operation at elevated ambient temperature can result in exceeding the maximum allowed junction temperature of 150§ C.
Note 2: The typical junction-to-ambient thermal resistance of the molded plastic DIP (N) is 105§ C/W, the molded plastic SO (M) package is 155§ C/W, and the
cerdip (J) package is 125§ C/W. All numbers apply for packages soldered directly into a printed circuit board.
Note 3: Limits are guaranteed by testing or correlation.
Note 4: For single supply operation, the following conditions apply: V a e 5V, Vb e 0V, VCM e 2.5V, VOUT e 2.5V. Pin 1 & Pin 8 (Vos Adjust) are each
connected to Pin 4 (Vb) to realize maximum output swing. This connection will degrade VOS, VOS Drift, and Input Voltage Noise.
Note 5: CL s 5 pF.
Note 6: In order to achieve optimum AC performance, the input stage was designed without protective clamps. Exceeding the maximum differential input voltage
results in reverse breakdown of the base-emitter junction of one of the input transistors and probable degradation of the input parameters (especially Vos, Ios, and
Noise).
Note 7: The average voltage that the weakest pin combinations (those involving Pin 2 or Pin 3) can withstand and still conform to the datasheet limits. The test
circuit used consists of the human body model of 100 pF in series with 1500X.
Note 8: VIN e 8V step. For supply e g 5V, VIN e 5V step.
Note 9: Voltage Gain is the total output swing (20V) divided by the input signal required to produce that swing.
Note 10: The voltage between V a and either input pin must not exceed 36V.
Note 11: A military RETS electrical test specification is available on request. At the time of printing, the RETS6161X specs complied with all Boldface limits in this
column.
Note 12: 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 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.
3
Typical Performance Characteristics (RL e 10 kX, TA e 25§ C unless otherwise specified)
Supply Current vs
Supply Voltage
Common-Mode
Rejection Ratio
Power Supply
Rejection Ratio
Gain-Bandwidth
Product
Propagation Delay
Rise and Fall Times
Gain-Bandwidth Product
vs Load Capacitance
Slew Rate vs
Load Capacitance
Overshoot vs
Capacitive Load
Slew Rate
Voltage Gain
vs Load Resistance
Gain vs Supply Voltage
TL/H/9057 – 6
4
Typical Performance Characteristics
(RL e 10 kX, TA e 25§ C unless otherwise specified) (Continued)
Differential Gain (Note)
Differential Phase (Note)
TL/H/9057 – 8
Note: Differential gain and differential phase measured for four series
LM6361 op amps configured as unity-gain followers, in series with an
LM6321 buffer. Error added by LM6321 is negligible. Test performed using
Tektronix Type 520 NTSC test system.
TL/H/9057 – 7
Input (2V/div) Output (2V/div)
Step Response; Av e a 1
(50 ns/div)
Input Noise Voltage
Input Noise Current
TL/H/9057 – 1
Power Bandwidth
TL/H/9057 – 9
5
Typical Performance Characteristics
(RL e 10 kX, TA e 25§ C unless otherwise specified) (Continued)
Open-Loop
Frequency Response
Open-Loop
Frequency Response
Output Impedence
(Open-Loop)
Common-Mode Input
Saturation Voltage
Output Saturation Voltage
Bias Current vs
Common-Mode Voltage
TL/H/9057 – 12
Simplified Schematic
TL/H/9057 – 3
6
Applications Tips
however, improve the stability and transient response and is
recommended for every design. 0.01 mF to 0.1 mF ceramic
capacitors should be used (from each supply ‘‘rail’’ to
ground); if the device is far away from its power supply
source, an additional 2.2 mF to 10 mF of tantalum may provide extra noise reduction.
Keep all leads short to reduce stray capacitance and lead
inductance, and make sure ground paths are low-impedance, especially where heavier currents will be flowing.
Stray capacitance in the circuit layout can cause signal coupling across adjacent nodes and can cause gain to unintentionally vary with frequency.
Breadboarded circuits will work best if they are built using
generic PC boards with a good ground plane. If the op amps
are used with sockets, as opposed to being soldered into
the circuit, the additional input capacitance may degrade
circuit performance.
The LM6361 has been compensated for unity-gain operation. Since this compensation involved adding emitter-degeneration resistors to the op amp’s input stage, the openloop gain was reduced as the stability increased. Gain error
due to reduced AVOL is most apparent at high gains; thus,
for gains between 5 and 25, the less-compensated LM6364
should be used, and the uncompensated LM6365 is appropriate for gains of 25 or more. The LM6361, LM6364, and
LM6365 have the same high slew rate, regardless of their
compensation.
The LM6361 is unusually tolerant of capacitive loads. Most
op amps tend to oscillate when their load capacitance is
greater than about 200 pF (especially in low-gain circuits).
The LM6361’s compensation is effectively increased with
load capacitance, reducing its bandwidth and increasing its
stability.
Power supply bypassing is not as critical for the LM6361 as
it is for other op amps in its speed class. Bypassing will,
Typical Applications
Offset Voltage Adjustment
1 MHz Low-Pass Filter
TL/H/9057–4
TL/H/9057 – 10
² 1% tolerance
*Matching determines filter precision
fc e (2q 0(R1 R2 C1 C2))b1
Modulator with Differential-to-Single-Ended Converter
TL/H/9057 – 11
7
Physical Dimensions inches (millimeters)
20-Lead Small Outline Package (E)
Order Number LM6161E/883
NS Package Number E20A
Ceramic Dual-In-Line Package (J)
Order Number LM6161J/883
NS Package Number J08A
8
Physical Dimensions inches (millimeters) (Continued)
Molded Package SO (M)
Order Number LM6261M or LM6361M
NS Package Number M08A
Molded Dual-In-Line Package (N)
Order Number LM6261N or LM6361N
NS Package Number N08E
9
LM6161/LM6261/LM6361 High Speed Operational Amplifier
Physical Dimensions inches (millimeters) (Continued)
10-Pin Ceramic Flatpak
Order Number LM6161W/883
NS Package Number W10A
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