LM6144 - National Semiconductor

LM6142 Dual and LM6144 Quad

High Speed/Low Power 17 MHz Rail-to-Rail Input-Output

Operational Amplifiers

General Description

Using patent pending new circuit topologies, the LM6142/44

provides new levels of performance in applications where

low voltage supplies or power limitations previously made

compromise necessary. Operating on supplies of 1.8V to

over 24V, the LM6142/44 is an excellent choice for battery

operated systems, portable instrumentation and others.

The greater than rail-to-rail input voltage range eliminates

concern over exceeding the common-mode voltage range.

The rail-to-rail output swing provides the maximum possible

dynamic range at the output. This is particularly important

when operating on low supply voltages.

High gain-bandwidth with 650 µA/Amplifier supply current

opens new battery powered applications where previous

higher power consumption reduced battery life to unaccept-

able levels. The ability to drive large capacitive loads without

oscillating functionally removes this common problem.

Features

At V

=5V. Typ unless noted.

nRail-to-rail input CMVR −0.25V to 5.25V

nRail-to-rail output swing 0.005V to 4.995V

nWide gain-bandwidth: 17 MHz at 50 kHz (typ)

nSlew rate:

Small signal, 5V/µs

Large signal, 30V/µs

nLow supply current 650 µA/Amplifier

nWide supply range 1.8V to 24V

nCMRR 107 dB

nGain 108 dB with R

=10k

nPSRR 87 dB

Applications

nBattery operated instrumentation

nDepth sounders/fish finders

nBarcode scanners

nWireless communications

nRail-to-rail in-out instrumentation amps

Connection Diagrams

8-Pin CDIP

DS012057-14

Top View

8-Pin DIP/SO

DS012057-1

Top View

May 1999

LM6142 Dual and LM6144 Quad High Speed/Low Power 17 MHz Rail-to-Rail Input-Output

Operational Amplifiers

Connection Diagrams (Continued)

Ordering Information

Package Temperature Range Temperature Range NSC

Drawing

Industrial Military

−40˚C to +85˚C −55˚C to +125˚C

8-Pin Molded DIP LM6142AIN, LM6142BIN N08E

8-Pin Small Outline LM6142AIM, LM6142BIM M08A

14-Pin Molded DIP LM6144AIN, LM6144BIN N14A

14-Pin Small Outline LM6144AIM, LM6144BIM M14A

8-Pin CDIP LM6142AMJ-QML J08A

14-Pin DIP/SO

DS012057-2

Top View

www.national.com 2

Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,

please contact the National Semiconductor Sales Office/

Distributors for availability and specifications.

ESD Tolerance (Note 2) 2500V

Differential Input Voltage 15V

Voltage at Input/Output Pin (V+) + 0.3V, (V−) − 0.3V

Supply Voltage (V+ − V−) 35V

Current at Input Pin ±10 mA

Current at Output Pin (Note 3) ±25 mA

Current at Power Supply Pin 50 mA

Lead Temperature

(soldering, 10 sec) 260˚C

Storage Temp. Range −65˚C to +150˚C

Junction Temperature (Note 4) 150˚C

Operating Ratings (Note 1)

Supply Voltage 1.8V ≤V+ ≤24V

Junction Temperature Range

LM6142, LM6144 −40˚C ≤T

≤+85˚C

Thermal Resistance (θ

)

N Package, 8-Pin Molded DIP 115˚C/W

M Package, 8-Pin Surface Mount 193˚C/W

N Package, 14-Pin Molded DIP 81˚C/W

M Package, 14-Pin Surface Mount 126˚C/W

5.0V DC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T

=25˚C, V+ =5.0V, V− =0V, V

=V+/2 and R

>1MΩto

V+/2. Boldface limits apply at the temperature extremes.

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

Input Offset Voltage 0.3 1.0 2.5 mV

2.2 3.3 max

TCV

Input Offset Voltage 3µV/˚C

Average Drift

Input Bias Current 170 250 300 nA

max

0V ≤V

≤5V 180 280

526 526

Input Offset Current 3 30 30 nA

80 80 max

Input Resistance, C

126 MΩ

CMRR Common Mode 0V ≤V

≤4V 107 84 84

min

Rejection Ratio 78 78

0V ≤V

≤5V 82 66 66

79 64 64

PSRR Power Supply 5V ≤V

≤24V 87 80 80

Rejection Ratio 78 78

Input Common-Mode −0.25 00V

Voltage Range 5.25 5.0 5.0

Large Signal R

=10k 270 100 80 V/mV

Voltage Gain 70 33 25 min

Output Swing R

=100k 0.005 0.01 0.01 V

0.013 0.013 max

4.995 4.98 4.98 V

4.93 4.93 min

=10k 0.02 V max

4.97 V min

=2k 0.06 0.1 0.1 V

0.133 0.133 max

4.90 4.86 4.86 V

4.80 4.80 min

www.national.com3

5.0V DC Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for T

=25˚C, V+ =5.0V, V− =0V, V

=V+/2 and R

>1MΩto

V+/2. Boldface limits apply at the temperature extremes.

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

Output Short Sourcing 13 10 8 mA

Circuit Current 4.9 4 min

LM6142 35 35 mA

max

Sinking 24 10 10 mA

5.3 5.3 min

35 35 mA

max

Output Short Sourcing 8 6 6 mA

Circuit Current 33min

LM6144 35 35 mA

max

Sinking 22 8 8 mA

44min

35 35 mA

max

Supply Current Per Amplifier 650 800 800 µA

880 880 max

5.0V AC Electrical Characteristics

Unless Otherwise Specified, All Limits Guaranteed for T

=25˚C, V+ =5.0V, V− =0V, V

=V+/2 and R

>1MΩto

/2. Boldface limits apply at the temperature extremes.

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

SR Slew Rate 8 V

p-p

12V 25 15 13 V/µs

>1kΩ13 11 min

GBW Gain-Bandwidth Product f =50 kHz 17 10 10 MHz

66min

Phase Margin 38 Deg

Amp-to-Amp Isolation 130 dB

Input-Referred f =1 kHz 16

Voltage Noise

Input-Referred f =1 kHz 0.22

Current Noise

T.H.D. Total Harmonic Distortion f =10 kHz, R

=10 kΩ, 0.003 %

www.national.com 4

2.7V DC Electrical Characteristics

Unless Otherwise Specified, All Limits Guaranteed for T

=25˚C, V+ =2.7V, V− =0V, V

=V+/2 and R

>1MΩto

/2. Boldface limits apply at the temperature extreme

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

Input Offset Voltage 0.4 1.8 2.5 mV

4.3 4.3 max

Input Bias Current 150 250 300 nA

526 526 max

Input Offset Current 4 30 30 nA

80 80 max

Input Resistance 128 MΩ

CMRR Common Mode 0V ≤V

≤1.8V 90 dB

min

Rejection Ratio 0V ≤V

≤2.7V 76

PSRR Power Supply 3V ≤V+ ≤5V 79

Rejection Ratio

Input Common-Mode −0.25 0 0 V min

Voltage Range 2.95 2.7 2.7 V max

Large Signal R

=10k 55 V/mV

Voltage Gain min

Output Swing R

=10 kΩ0.019 0.08 0.08 V

0.112 0.112 max

2.67 2.66 2.66 V

2.25 2.25 min

Supply Current Per Amplifier 510 800 800 µA

880 880 max

2.7V AC Electrical Characteristics

Unless Otherwise Specified, All Limits Guaranteed for T

=25˚C, V+ =2.7V, V− =0V, V

=V+/2 and R

>1MΩto

/2. Boldface limits apply at the temperature extreme

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

GBW Gain-Bandwidth Product f =50 kHz 9 MHz

Phase Margin 36 Deg

Gain Margin 6 dB

www.national.com5

24V Electrical Characteristics

Unless Otherwise Specified, All Limits Guaranteed for T

=25˚C, V+ =24V, V− =0V, V

=V+/2 and R

>1MΩto

/2. Boldface limits apply at the temperature extreme

LM6144AI LM6144BI

Symbol Parameter Conditions Typ LM6142AI LM6142BI Units

(Note 5) Limit Limit

(Note 6) (Note 6)

Input Offset Voltage 1.3 2 3.8 mV

4.8 4.8 max

Input Bias Current 174 nA

max

Input Offset Current 5 nA

max

Input Resistance 288 MΩ

CMRR Common Mode 0V ≤V

≤23V 114 dB

min

Rejection Ratio 0V ≤V

≤24V 100

PSRR Power Supply 0V ≤V

≤24V 87

Rejection Ratio

Input Common-Mode −0.25 0 0 V min

Voltage Range 24.25 24 24 V max

Large Signal R

=10k 500 V/mV

Voltage Gain min

Output Swing R

=10 kΩ0.07 0.15 0.15 V

0.185 0.185 max

23.85 23.81 23.81 V

23.62 23.62 min

Supply Current Per Amplifier 750 1100 1100 µA

1150 1150 max

GBW Gain-Bandwidth Product f =50 kHz 18 MHz

Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is in-

tended to be functional, but specific performance is not guaranteed. For guaranteed specifications and the test conditions, see the Electrical Charactenstics.

Note 2: Human body model, 1.5 kΩin series with 100 pF.

Note 3: Applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated ambient temperature can result in exceeding the

maximum allowed junction temperature of 150˚C.

Note 4: The maximum power dissipation is a function of TJ(max),θJA, and TA. The maximum allowable power dissipation at any ambient temperature is PD=(Tj(max)

−T

)/θJA. All numbers apply for packages soldered directly into a PC board.

Note 5: Typical values represent the most likely parametric norm.

Note 6: All limits are guaranteed by testing or statistical analysis.

Note 7: For guaranteed military specifications see military datasheet MNLM6142AM-X.

www.national.com 6

Typical Performance Characteristics T

=25˚C, R

=10 kΩUnless Otherwise Specified

Supply Current vs

Supply Voltage

DS012057-15

Offset Voltage vs

Supply Voltage

DS012057-16

Bias Current vs

Supply Voltage

DS012057-17

Offset Voltage vs V

DS012057-18

Offset Voltage vs V

DS012057-19

Offset Voltage vs V

DS012057-20

Bias Current vs V

DS012057-21

Bias Current vs V

DS012057-22

Bias Current vs V

DS012057-23

Open-Loop Transfer

Function

DS012057-24

Open-Loop Transfer

Function

DS012057-25

Open-Loop Transfer

Function

DS012057-26

www.national.com7

Typical Performance Characteristics T

=25˚C, R

=10 kΩUnless Otherwise

Specified (Continued)

Output Voltage vs

Source Current

DS012057-27

Output Voltage vs

Source Current

DS012057-28

Output Voltage vs

Source Current

DS012057-29

Output Voltage vs

Sink Current

DS012057-30

Output Voltage vs

Sink Current

DS012057-31

Output Voltage vs

Sink Current

DS012057-32

Gain and Phase vs Load

DS012057-33

Gain and Phase vs Load

DS012057-34

Distortion + Noise

vs Frequency

DS012057-35

www.national.com 8

Typical Performance Characteristics T

=25˚C, R

=10 kΩUnless Otherwise

Specified (Continued)

GBW vs Supply

DS012057-36

Open Loop Gain vs

Load, 3V Supply

DS012057-37

Open Loop Gain vs

Load, 5V Supply

DS012057-38

Open Loop Gain vs

Load, 24V Supply

DS012057-39

Unity Gain Freq vs V

DS012057-40

CMRR vs Frequency

DS012057-41

Crosstalk vs Frequency

DS012057-42

PSRR vs Frequency

DS012057-43

Noise Voltage vs Frequency

DS012057-44

www.national.com9

Typical Performance Characteristics T

=25˚C, R

=10 kΩUnless Otherwise

Specified (Continued)

LM6142/44 Application Ideas

The LM6142 brings a new level of ease of use to opamp sys-

tem design.

With greater than rail-to-rail input voltage range concern

over exceeding the common-mode voltage range is elimi-

nated.

Rail-to-rail output swing provides the maximum possible dy-

namic range at the output. This is particularly important

when operating on low supply voltages.

The high gain-bandwidth with low supply current opens new

battery powered applications, where high power consump-

tion, previously reduced battery life to unacceptable levels.

To take advantage of these features, some ideas should be

kept in mind.

ENHANCED SLEW RATE

Unlike most bipolar opamps, the unique phase reversal

prevention/speed-up circuit in the input stage causes the

slew rate to be very much a function of the input signal am-

plitude.

Figure 2

shows how excess input signal, is routed around

the input collector-base junctions, directly to the current mir-

rors.

The LM6142/44 input stage converts the input voltage

change to a current change. This current change drives the

current mirrors through the collectors of Q1–Q2, Q3–Q4

when the input levels are normal.

If the input signal exceeds the slew rate of the input stage,

the differential input voltage rises above two diode drops.

This excess signal bypasses the normal input transistors,

(Q1–Q4), and is routed in correct phase through the two ad-

ditional transistors, (Q5, Q6), directly into the current mirrors.

This rerouting of excess signal allows the slew-rate to in-

crease by a factor of 10 to 1 or more. (See

Figure 1

As the overdrive increases, the opamp reacts better than a

conventional opamp. Large fast pulses will raise the slew-

rate to around 30V to 60V/µs.

This effect is most noticeable at higher supply voltages and

lower gains where incoming signals are likely to be large.

This new input circuit also eliminates the phase reversal

seen in many opamps when they are overdriven.

This speed-up action adds stability to the system when driv-

ing large capacitive loads.

DRIVING CAPACITIVE LOADS

Capacitive loads decrease the phase margin of all opamps.

This is caused by the output resistance of the amplifier and

the load capacitance forming an R-C phase lag network.

This can lead to overshoot, ringing and oscillation. Slew rate

limiting can also cause additional lag. Most opamps with a

fixed maximum slew-rate will lag further and further behind

when driving capacitive loads even though the differential in-

put voltage raises. With the LM6142, the lag causes the slew

rate to raise. The increased slew-rate keeps the output fol-

lowing the input much better. This effectively reduces phase

lag. After the output has caught up with the input, the differ-

ential input voltage drops down and the amplifier settles

rapidly.

Noise Current vs Frequency

DS012057-45

NE vs R Source

DS012057-12

Slew Rate vs ∆V

=±5V

DS012057-7

FIGURE 1.

www.national.com 10

LM6142/44 Application Ideas (Continued)

These features allow the LM6142 to drive capacitive loads

as large as 1000 pF at unity gain and not oscillate. The

scope photos (

Figure 3

and

Figure 4

) above show the

LM6142 driving a l000 pF load. In

Figure 3

, the upper trace

is with no capacitive load and the lower trace is with a 1000

pF load. Here we are operating on ±12V supplies with a 20

Vp-p pulse. Excellent response is obtained with a C

of l0 pF.

Figure 4

, the supplies have been reduced to ±2.5V, the

pulse is 4 Vp-p and C

is 39 pF. The best value for the com-

pensation capacitor is best established after the board layout

is finished because the value is dependent on board stray

capacity, the value of the feedback resistor, the closed loop

gain and, to some extent, the supply voltage.

Another effect that is common to all opamps is the phase

shift caused by the feedback resistor and the input capaci-

tance. This phase shift also reduces phase margin. This ef-

fect is taken care of at the same time as the effect of the ca-

pacitive load when the capacitor is placed across the

feedback resistor.

The circuit shown in

Figure 5

was used for these scope

photos.

Typical Applications

FISH FINDER/ DEPTH SOUNDER.

The LM6142/44 is an excellent choice for battery operated

fish finders. The low supply current, high gain-bandwidth and

full rail to rail output swing of the LM6142 provides an ideal

combination for use in this and similar applications.

DS012057-6

FIGURE 2.

DS012057-8

FIGURE 3.

DS012057-9

FIGURE 4.

DS012057-10

FIGURE 5.

www.national.com11

Typical Applications (Continued)

ANALOG TO DIGITAL CONVERTER BUFFER

The high capacitive load driving ability, rail-to-rail input and

output range with the excellent CMR of 82 dB, make the

LM6142/44 a good choice for buffering the inputs of A to D

converters.

3 OPAMP INSTRUMENTATION AMP WITH

RAIL-TO-RAIL INPUT AND OUTPUT

Using the LM6144, a 3 opamp instrumentation amplifier with

rail-to-rail inputs and rail to rail output can be made. These

features make these instrumentation amplifiers ideal for

single supply systems.

Some manufacturers use a precision voltage divider array of

5 resistors to divide the common-mode voltage to get an in-

put range of rail-to-rail or greater. The problem with this

method is that it also divides the signal, so to even get unity

gain, the amplifier must be run at high closed loop gains.

This raises the noise and drift by the internal gain factor and

lowers the input impedance. Any mismatch in these preci-

sion resistors reduces the CMR as well. Using the LM6144,

all of these problems are eliminated.

In this example, amplifiers A and B act as buffers to the dif-

ferential stage (

Figure 6

). These buffers assure that the input

impedance is over 100 MΩand they eliminate the require-

ment for precision matched resistors in the input stage. They

also assure that the difference amp is driven from a voltage

source. This is necessary to maintain the CMR set by the

matching of R1–R2 with R3–R4.

The gain is set by the ratio of R2/R1 and R3 should equal R1

and R4 equal R2. Making R4 slightly smaller than R2 and

adding a trim pot equal to twice the difference between R2

and R4 will allow the CMR to be adjusted for optimum.

With both rail to rail input and output ranges, the inputs and

outputs are only limited by the supply voltages. Remember

that even with rail-to-rail output, the output can not swing

past the supplies so the combined common mode voltage

plus the signal should not be greater than the supplies or lim-

iting will occur.

SPICE MACROMODEL

A SPICE macromodel of this and many other National Semi-

conductor opamps is available at no charge from the NSC

Customer Response Group at 800-272-9959.

DS012057-13

FIGURE 6.

www.national.com 12

Physical Dimensions inches (millimeters) unless otherwise noted

8-Pin Ceramic Sidebrazed

Dual-In-Line Package

Order Number LM6142AMJ-QML

NS Package Number D08C

8-Pin Small Outline Package

Order Number LM6142AIM or LM6142BIM

NS Package Number M08A

www.national.com13

Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

14-Pin Small Outline Package

Order Number LM6144AIM or LM6144BIM

NS Package Number M14A

8-Pin Molded Dual-In-Line Package

Order Number LM6142AIN or LM6142BIN

NS Package Number N08E

www.national.com 14

Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

LIFE SUPPORT POLICY

NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT

DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL

COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:

1. Life support devices or systems are devices or

systems which, (a) are intended for surgical implant

into the body, or (b) support or sustain life, and

whose failure to perform when properly used in

accordance with instructions for use provided in the

labeling, can be reasonably expected to result in a

significant injury to the user.

2. A critical component is any component of a life

support device or system whose failure to perform

can be reasonably expected to cause the failure of

the life support device or system, or to affect its

safety or effectiveness.

National Semiconductor

Corporation

Americas

Tel: 1-800-272-9959

Fax: 1-800-737-7018

Email: support@nsc.com

National Semiconductor

Europe Fax: +49 (0) 1 80-530 85 86

Email: europe.support@nsc.com

Deutsch Tel: +49 (0) 1 80-530 85 85

English Tel: +49 (0) 1 80-532 78 32

Français Tel: +49 (0) 1 80-532 93 58

Italiano Tel: +49 (0) 1 80-534 16 80

National Semiconductor

Asia Pacific Customer

Response Group

Tel: 65-2544466

Fax: 65-2504466

Email: sea.support@nsc.com

National Semiconductor

Japan Ltd.

Tel: 81-3-5639-7560

Fax: 81-3-5639-7507

www.national.com

14-Pin Molded Dual-In-Line Package

Order Number LM6144AIN or LM6144BIN

NS Package Number N14A

LM6142 Dual and LM6144 Quad High Speed/Low Power 17 MHz Rail-to-Rail Input-Output

Operational Amplifiers

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.