TI1 LM6172AMGWRLQV Dual high speed, low power, low distortion, voltage feedback amplifier Datasheet

LM6172QML
LM6172QML Dual High Speed, Low Power, Low Distortion, Voltage Feedback
Amplifiers
Literature Number: SNOSAR4A
LM6172QML
Dual High Speed, Low Power, Low Distortion, Voltage
Feedback Amplifiers
General Description
Features
The LM6172 is a dual high speed voltage feedback amplifier.
It is unity-gain stable and provides excellent DC and AC performance. With 100MHz unity-gain bandwidth, 3000V/μs slew
rate and 50mA of output current per channel, the LM6172 offers high performance in dual amplifiers; yet it only consumes
2.3mA of supply current each channel.
The LM6172 operates on ±15V power supply for systems requiring large voltage swings, such as ADSL, scanners and
ultrasound equipment. It is also specified at ±5V power supply
for low voltage applications such as portable video systems.
The LM6172 is built with National's advanced VIP® III (Vertically Integrated PNP) complementary bipolar process.
■ Available with Radiation Guarantee
■
■
■
■
■
■
— High Dose Rate
— ELDRS Free
Easy to Use Voltage Feedback Topology
High Slew Rate 3000V/μs
Wide Unity-Gain Bandwidth 100MHz
Low Supply Current 2.3mA / Amplifier
High Output Current 50mA / Amplifier
Specified for ±15V and ±5V operation
300 krad(Si)
100 krad(Si)
Applications
■
■
■
■
■
■
■
Scanner I- to -V Converters
ADSL/HDSL Drivers
Multimedia Broadcast Systems
Video Amplifiers
NTSC, PAL® and SECAM Systems
ADC/DAC Buffers
Pulse Amplifiers and Peak Detectors
Ordering Information
SMD Part Number
NS Package Number
Package Description
LM6172AMJ-QML
NS Part Number
5962-9560401QPA
J08A
8LD Ceramic Dip
LM6172AMJFQML
5962F9560401QPA
300 krad(Si)
J08A
8LD Ceramic Dip
LM6172AMJFQMLV
5962F9560401VPA
300 krad(Si)
J08A
8LD Ceramic Dip
LM6172AMWG-QML
5962-9560401QXA
WG16A
10LD Ceramic SOIC
LM6172AMWGFQMLV
5962F9560401VXA
300 krad(Si)
WG16A
10LD Ceramic SOIC
LM6172AMGW-QML
5962-9560402QXA
WG16A
10LD Ceramic SOIC
LM6172AMGWFQMLV
5962F9560402VXA
300 krad(Si)
WG16A
10LD Ceramic SOIC
LM6172AMGWRLQV
ELDRS FREE(Note 15)
5962R9560403VXA
100 krad(Si)
WG16A
10LD Ceramic SOIC
LM6172 MDR
5962F9560401V9A
300 krad(Si)
(Note 1)
Bare Die
LM6172–MDE
ELDRS FREE(Note 15)
5962R9560403V9A
100 krad(Si)
(Note 1)
Bare Die
Note 1: FOR ADDITIONAL DIE INFORMATION, PLEASE VISIT THE HI REL WEB SITE AT: www.national.com/analog/space/level_die
VIP® is a registered trademark of National Semiconductor Corporation.
PAL® is a registered trademark of and used under lisence from Advanced Micro Devices, Inc.
© 2011 National Semiconductor Corporation
201594
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LM6172QML Dual High Speed, Low Power, Low Distortion, Voltage Feedback Amplifiers
October 5, 2011
LM6172QML
Connection Diagrams
8-Pin DIP
16LD Ceramic SOIC
20159401
Top View
20159459
Top View
LM6172 Driving Capacitive Load
20159444
20159450
LM6172 Simplified Schematic (Each Amplifier)
20159455
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2
LM6172QML
Absolute Maximum Ratings (Note 2)
Supply Voltage (V+ − V−)
Differential Input Voltage (Note 7)
Maximum Junction Temperature
Power Dissipation (Note 3), (Note 4)
Output Short Circuit to Ground (Note 6)
Storage Temperature Range
36V
±10V
150°C
1.03W
Continuous
−65°C ≤ TA ≤ +150°C
V+ +0.3V to V− −0.3V
±10mA
Common Mode Voltage Range
Input Current
Thermal Resistance (Note 8)
θJA
8LD Ceramic Dip (Still Air)
8LD Ceramic Dip (500LF/Min Air Flow)
16LD Ceramic SOIC (Still Air) “WG”
16LD Ceramic SOIC (500LF/Min Air Flow) “WG”
16LD Ceramic SOIC (Still Air) “GW”
16LD Ceramic SOIC (500LF/Min Air Flow) “GW”
100°C/W
46°C/W
124°C/W
74°C/W
135°C/W
85°C/W
θJC
8LD Ceramic Dip (Note 4)
16LD Ceramic SOIC “WG”(Note 4)
16LD Ceramic SOIC “GW”
Package Weight
8LD Ceramic Dip
16LD Ceramic SOIC “WG”
16LD Ceramic SOIC “GW”
ESD Tolerance (Note 5)
2°C/W
6°C/W
7°C/W
980mg
365mg
410mg
4KV
Recommended Operating Conditions
(Note 2)
5.5V ≤ VS ≤ 36V
Supply Voltage
−55°C ≤ TA ≤ +125°C
Operating Temperature Range
Quality Conformance Inspection
Mil-Std-883, Method 5005 - Group A
Subgroup
Description
Temp (°C)
1
Static tests at
+25
2
Static tests at
+125
3
Static tests at
-55
4
Dynamic tests at
+25
5
Dynamic tests at
+125
6
Dynamic tests at
-55
7
Functional tests at
+25
8A
Functional tests at
+125
8B
Functional tests at
-55
9
Switching tests at
+25
10
Switching tests at
+125
11
Switching tests at
-55
12
Settling time at
+25
13
Settling time at
+125
14
Settling time at
-55
3
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LM6172QML
LM6172 (±5V) Electrical Characteristics
(Note 14)
DC Parameters
The following conditions apply, unless otherwise specified.
Symbol
VIO
Parameter
TJ = 25°C, V+ = +5V, V− = −5V, VCM = 0V & RL > 1MΩ
Conditions
Input Bias Current
IIO
Input Offset Current
CMRR
Common Mode Rejection Ratio
VCM = ±2.5V
PSRR
Power Supply Rejection Ratio
VS = ±15V to ±5V
RL = 1KΩ
Large Signal Voltage Gain
RL = 100Ω
Output Current (Open Loop)
Sinking RL = 100Ω
IS
Supply Current
DC Drift Parameters
Subgroups
1.0
mV
1
3.0
mV
2, 3
2.5
µA
1
3.5
µA
2, 3
1.5
µA
1
2.2
µA
2, 3
1
65
dB
2, 3
75
dB
1
70
dB
2, 3
(Note 9)
70
dB
1
(Note 9)
65
dB
2, 3
(Note 9)
65
dB
1
(Note 9)
60
dB
2, 3
RL = 100Ω
IL
Units
dB
Output Swing
Sourcing RL = 100Ω
Max
70
RL = 1KΩ
VO
Min
Input Offset Voltage
IIB
AV
Notes
3.1
-3.1
V
1
3.0
-3.0
V
2, 3
2.5
-2.4
V
1
2.4
-2.3
V
2, 3
(Note 13)
25
mA
1
(Note 13)
24
mA
2, 3
(Note 13)
-24
mA
1
(Note 13)
-23
mA
2, 3
6.0
mA
1
7.0
mA
2, 3
Both Amplifiers
(Note 14)
The following conditions apply, unless otherwise specified. TJ = 25°C, V+ = +5V, V− = −5V, VCM = 0V & RL > 1MΩ
Delta calculations performed on QMLV devices at group B , subgroup 5.
Symbol
Parameter
Conditions
Notes
Min
Max
Units
Subgroups
VIO
Input Offset Voltage
-0.25
0.25
mV
1
IIB
Input Bias Current
-0.50
0.50
µA
1
IIO
Input Ofset Current
-0.25
0.25
µA
1
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LM6172QML
LM6172 (±15V) Electrical Characteristics
DC Parameters
(Note 14)
The following conditions apply, unless otherwise specified.
Symbol
VIO
Parameter
TJ = 25°C, V+ = +15V, V− = −15V, VCM = 0V, & RL = 1MΩ
Conditions
Input Bias Current
IIO
Input Offset Current
CMRR
Common Mode Rejection Ratio
VCM = ±10V
PSRR
Power Supply Rejection Ratio
VS = ±15V to ±5V
RL = 1KΩ
Large Signal Voltage Gain
RL = 100Ω
Sinking RL = 100Ω
IS
Supply Current
1.5
mV
1
3.5
mV
2, 3
3.0
µA
1
4.0
µA
2, 3
2.0
µA
1
3.0
µA
2, 3
1
dB
2, 3
75
dB
1
70
dB
2, 3
(Note 9)
75
dB
1
(Note 9)
70
dB
2, 3
(Note 9)
65
dB
1
(Note 9)
60
dB
2, 3
-12.5
V
1
2, 3
Output Swing
Output Current (Open Loop)
Subgroups
65
RL = 100Ω
IL
Units
dB
12.5
Sourcing RL = 100Ω
Max
70
RL = 1KΩ
VO
Min
Input Offset Voltage
IIB
AV
Notes
12
-12
V
6.0
-6.0
V
1
5.0
-5.0
V
2, 3
(Note 13)
60
mA
1
(Note 13)
50
mA
2, 3
(Note 13)
-60
mA
1
(Note 13)
-50
mA
2, 3
8.0
mA
1
9.0
mA
2, 3
Units
Subgroups
Both Amplifiers
AC Parameters
(Note 14)
The following conditions apply, unless otherwise specified.
Symbol
Parameter
TJ = 25°C, V+ = +15V, V− = −15V, VCM = 0V
Conditions
AV = 2, VI = ±2.5V
3nS Rise & Fall time
SR
Slew Rate
GBW
Unity-Gain Bandwidth
Notes
Min
Max
(Note 10),
(Note 11)
1700
V/µS
4
(Note 12)
80
MHz
4
DC Drift Parameters
(Note 14)
The following conditions apply, unless otherwise specified. TJ = 25°C, V+ = +15V, V− = −15V, VCM = 0V
Delta calculations performed on QMLV devices at group B , subgroup 5.
Symbol
Parameter
Conditions
Notes
Min
Max
Units
Subgroups
VIO
Input Offset Voltage
-0.25
0.25
mV
1
IIB
Input Bias Current
-0.50
0.50
µA
1
IIO
Input Offset Current
-0.25
0.25
µA
1
5
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LM6172QML
Note 2: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
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. Some performance characteristics may degrade when the device is not operated under the listed test
conditions.
Note 3: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJmax (maximum junction temperature), θJA (package
junction to ambient thermal resistance), and TA (ambient temperature). The maximum allowable power dissipation at any temperature is PDmax = (TJmax - TA)/
θJA or the number given in the Absolute Maximum Ratings, whichever is lower.
Note 4: The package material for these devices allows much improved heat transfer over our standard ceramic packages. In order to take full advantage of this
improved heat transfer, heat sinking must be provided between the package base (directly beneath the die), and either metal traces on, or thermal vias through,
the printed circuit board. Without this additional heat sinking, device power dissipation must be calculated using θJA, rather than θJC, thermal resistance. It must
not be assumed that the device leads will provide substantial heat transfer out the package, since the thermal resistance of the leadframe material is very poor,
relative to the material of the package base. The stated θJC thermal resistance is for the package material only, and does not account for the additional thermal
resistance between the package base and the printed circuit board. The user must determine the value of the additional thermal resistance and must combine
this with the stated value for the package, to calculate the total allowed power dissipation for the device.
Note 5: Human body model, 1.5 kΩ in series with 100 pF.
Note 6: Continuous short circuit operation can result in exceeding the maximum allowed junction temperature of 150°C
Note 7: Differential Input Voltage is measured at VS = ±15V.
Note 8: All numbers apply for packages soldered directly into a PC board.
Note 9: Large signal voltage gain is the total output swing divided by the input signal required to produce that swing. For VS = ±15V, VOUT = ±5V. For VS = ±5V,
VOUT = ±1V.
Note 10: See AN0009 for SR test circuit.
Note 11: Slew Rate measured between ±4V.
Note 12: See AN0009 for GBW test circuit.
Note 13: The open loop output current is guaranteed by measurement of the open loop output voltage swing using 100Ω output load.
Note 14: Pre and post irradiation limits are identical to those listed under AC and DC electrical characteristics. These parts may be dose rate sensitive in a space
environment and demonstrate enhanced low dose rate effect. Radiation end point limits for the noted parameters are guaranteed only for the conditions as
specified in Mil-Std-883, Method 1019.5, Condition A.
Note 15: Low dose rate testing has been performed per test method 1019, condition D, MIL-STD-883, with no enhanced low dose rate sensitivity (ELDRS) effect.
Pre and post irradiation limits are identical to those listed under AC and DC electrical characteristics. Radiation end point limits for the noted parameters are
guaranteed for only the conditions as specified in MIL-STD-883, Method 1019, condition D. The “03” device has been characterized to only 100k.
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LM6172QML
Typical Performance Characteristics
Unless otherwise noted, TA = 25°C
Supply Voltage vs. Supply Current
Supply Current vs. Temperature
20159414
20159415
Input Offset Voltage vs. Temperature
Input Bias Current vs. Temperature
20159416
20159417
Short Circuit Current vs. Temperature (Sourcing)
Short Circuit Current vs. Temperature (Sinking)
20159435
20159418
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LM6172QML
Output Voltage vs. Output Current
(VS = ±15V)
Output Voltage vs. Output Current
(VS = ±5V)
20159436
20159437
CMRR vs. Frequency
PSRR vs. Frequency
20159420
20159419
PSRR vs. Frequency
Open-Loop Frequency Response
20159433
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20159421
8
Gain-Bandwidth Product vs. Supply Voltage at Different
Temperature
20159422
20159423
Large Signal Voltage Gain vs. Load
Large Signal Voltage Gain vs. Load
20159438
20159439
Input Voltage Noise vs. Frequency
Input Voltage Noise vs. Frequency
20159440
20159441
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LM6172QML
Open-Loop Frequency Response
LM6172QML
Input Current Noise vs. Frequency
Input Current Noise vs. Frequency
20159442
20159443
Slew Rate vs. Supply Voltage
Slew Rate vs. Input Voltage
20159426
20159425
Large Signal Pulse Response
AV = +1, VS = ±15V
Small Signal Pulse Response
AV = +1, VS = ±15V
20159402
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20159403
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LM6172QML
Large Signal Pulse Response
AV = +1, VS = ±5V
Small Signal Pulse Response
AV = +1, VS = ±5V
20159404
20159405
Large Signal Pulse Response
AV = +2, VS = ±15V
Small Signal Pulse Response
AV = +2, VS = ±15V
20159406
20159407
Large Signal Pulse Response
AV = +2, VS = ±5V
Small Signal Pulse Response
AV = +2, VS = ±5V
20159408
20159409
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LM6172QML
Large Signal Pulse Response
AV = −1, VS = ±15V
Small Signal Pulse Response
AV = −1, VS = ±15V
20159410
20159411
Large Signal Pulse Response
AV = −1, VS = ±5V
Small Signal Pulse Response
AV = −1, VS = ±5V
20159412
20159413
Closed Loop Frequency Response vs. Supply Voltage
(AV = +1)
Closed Loop Frequency Response vs. Supply Voltage
(AV = +2)
20159428
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20159429
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LM6172QML
Harmonic Distortion vs. Frequency
(VS = ±15V)
Harmonic Distortion vs. Frequency
(VS = ±5V)
20159430
20159434
Crosstalk Rejection vs. Frequency
Maximum Power Dissipation vs. Ambient Temperature
20159432
20159431
divided by the total degeneration resistor RE. Therefore, the
slew rate is proportional to the input voltage level, and the
higher slew rates are achievable in the lower gain configurations.
When a very fast large signal pulse is applied to the input of
an amplifier, some overshoot or undershoot occurs. By placing an external series resistor such as 1kΩ to the input of
LM6172, the slew rate is reduced to help lower the overshoot,
which reduces settling time.
Application Notes
LM6172 PERFORMANCE DISCUSSION
The LM6172 is a dual high-speed, low power, voltage feedback amplifier. It is unity-gain stable and offers outstanding
performance with only 2.3mA of supply current per channel.
The combination of 100MHz unity-gain bandwidth, 3000V/μs
slew rate, 50mA per channel output current and other attractive features makes it easy to implement the LM6172 in
various applications. Quiescent power of the LM6172 is
138mW operating at ±15V supply and 46mW at ±5V supply.
REDUCING SETTLING TIME
The LM6172 has a very fast slew rate that causes overshoot
and undershoot. To reduce settling time on LM6172, a 1kΩ
resistor can be placed in series with the input signal to decrease slew rate. A feedback capacitor can also be used to
reduce overshoot and undershoot. This feedback capacitor
serves as a zero to increase the stability of the amplifier circuit. A 2pF feedback capacitor is recommended for initial
evaluation. When the LM6172 is configured as a buffer, a
feedback resistor of 1kΩ must be added in parallel to the
feedback capacitor.
Another possible source of overshoot and undershoot comes
from capacitive load at the output. Please see the section
“Driving Capacitive Loads” for more detail.
LM6172 CIRCUIT OPERATION
The class AB input stage in LM6172 is fully symmetrical and
has a similar slewing characteristic to the current feedback
amplifiers. In the LM6172 Simplified Schematic (Page 2), Q1
through Q4 form the equivalent of the current feedback input
buffer, RE the equivalent of the feedback resistor, and stage
A buffers the inverting input. The triple-buffered output stage
isolates the gain stage from the load to provide low output
impedance.
LM6172 SLEW RATE CHARACTERISTIC
The slew rate of LM6172 is determined by the current available to charge and discharge an internal high impedance
node capacitor. This current is the differential input voltage
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LM6172QML
LAYOUT CONSIDERATION
DRIVING CAPACITIVE LOADS
Amplifiers driving capacitive loads can oscillate or have ringing at the output. To eliminate oscillation or reduce ringing, an
isolation resistor can be placed as shown in Figure 1. The
combination of the isolation resistor and the load capacitor
forms a pole to increase stability by adding more phase margin to the overall system. The desired performance depends
upon the value of the isolation resistor; the bigger the isolation
resistor, the more damped (slow) the pulse response becomes. For LM6172, a 50Ω isolation resistor is recommended
for initial evaluation.
Printed Circuit Boards And High Speed Op Amps
There are many things to consider when designing PC boards
for high speed op amps. Without proper caution, it is very easy
to have excessive ringing, oscillation and other degraded AC
performance in high speed circuits. As a rule, the signal traces
should be short and wide to provide low inductance and low
impedance paths. Any unused board space needs to be
grounded to reduce stray signal pickup. Critical components
should also be grounded at a common point to eliminate voltage drop. Sockets add capacitance to the board and can
affect frequency performance. It is better to solder the amplifier directly into the PC board without using any socket.
Using Probes
Active (FET) probes are ideal for taking high frequency measurements because they have wide bandwidth, high input
impedance and low input capacitance. However, the probe
ground leads provide a long ground loop that will produce errors in measurement. Instead, the probes can be grounded
directly by removing the ground leads and probe jackets and
using scope probe jacks.
20159445
Components Selection And Feedback Resistor
It is important in high speed applications to keep all component leads short because wires are inductive at high frequency. For discrete components, choose carbon compositiontype resistors and mica-type capacitors. Surface mount
components are preferred over discrete components for minimum inductive effect.
Large values of feedback resistors can couple with parasitic
capacitance and cause undesirable effects such as ringing or
oscillation in high speed amplifiers. For LM6172, a feedback
resistor less than 1kΩ gives optimal performance.
FIGURE 1. Isolation Resistor Used
to Drive Capacitive Load
COMPENSATION FOR INPUT CAPACITANCE
The combination of an amplifier's input capacitance with the
gain setting resistors adds a pole that can cause peaking or
oscillation. To solve this problem, a feedback capacitor with
a value
20159451
CF > (RG × CIN)/RF
FIGURE 2. The LM6172 Driving a 510pF Load
with a 30Ω Isolation Resistor
can be used to cancel that pole. For LM6172, a feedback capacitor of 2pF is recommended. Figure 4 illustrates the compensation circuit.
20159452
20159446
FIGURE 3. The LM6172 Driving a 220 pF Load
with a 50Ω Isolation Resistor
FIGURE 4. Compensating for Input Capacitance
POWER SUPPLY BYPASSING
Bypassing the power supply is necessary to maintain low
power supply impedance across frequency. Both positive and
negative power supplies should be bypassed individually by
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POWER DISSIPATION
The maximum power allowed to dissipate in a device is defined as:
PD = (TJ(max) − TA)/θJA
Where PD is the power dissipation in a device
TJ(max) is the maximum junction temperature
TA is the ambient temperature
θJA is the thermal resistance of a particular package
For example, for the LM6172 in a SO-16 package, the maximum power dissipation at 25°C ambient temperature is
1000mW.
Thermal resistance, θJA, depends on parameters such as die
size, package size and package material. The smaller the die
size and package, the higher θJA becomes. The 8-pin DIP
package has a lower thermal resistance (95°C/W) than that
of 8-pin SO (160°C/W). Therefore, for higher dissipation capability, use an 8-pin DIP package.
The total power dissipated in a device can be calculated as:
20159447
FIGURE 5. Power Supply Bypassing
TERMINATION
In high frequency applications, reflections occur if signals are
not properly terminated. Figure 6 shows a properly terminated
signal while Figure 7 shows an improperly terminated signal.
PD = PQ + PL
PQ is the quiescent power dissipated in a device with no load
connected at the output. PL is the power dissipated in the device with a load connected at the output; it is not the power
dissipated by the load.
Furthermore,
PQ: = supply current x total supply voltage with no load
PL: = output current x (voltage difference between supply
voltage and output voltage of the same supply)
For example, the total power dissipated by the LM6172 with
VS = ±15V and both channels swinging output voltage of 10V
into 1kΩ is
PD: = PQ + PL
: =
2[(2.3mA)(30V)] + 2[(10mA)(15V − 10V)]
: =
138mW + 100mW
: =
238mW
20159453
FIGURE 6. Properly Terminated Signal
20159454
FIGURE 7. Improperly Terminated Signal
15
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LM6172QML
To minimize reflection, coaxial cable with matching characteristic impedance to the signal source should be used. The
other end of the cable should be terminated with the same
value terminator or resistor. For the commonly used cables,
RG59 has 75Ω characteristic impedance, and RG58 has
50Ω characteristic impedance.
placing 0.01μF ceramic capacitors directly to power supply
pins and 2.2μF tantalum capacitors close to the power supply
pins.
LM6172QML
Application Circuits
I- to -V Converters
20159448
Differential Line Driver
20159449
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16
Released
Revision
12/08/2010
A
New Release, Corporate format
Section
1 MDS data sheet converted into one Corp. data
sheet format. MNLM6172AM-X-RH Rev 0A0 will be
archived.
Changes
10/05/2011
B
Features, Ordering Information, Abs Max
Ratings, Footnotes
Update Radiation, Add new ELDRS FREE die id,
'GW' NSID'S w/coresponding SMD numbers. Add
'GW' Theta JA & Theta JC along with weight.Add
Note 15, Modify Note 14. LM6172QML Rev A will be
archived.
17
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LM6172QML
Revision History
LM6172QML
Physical Dimensions inches (millimeters) unless otherwise noted
8-Lead Ceramic Dual-In-Line Package
ONS Package Number J08A
16-Lead Ceramic SOIC Package
NS Package Number WG16A
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18
LM6172QML
Notes
19
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LM6172QML Dual High Speed, Low Power, Low Distortion, Voltage Feedback Amplifiers
Notes
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