Datasheet LMC6684BIM, LMC6684AIM, LMC6682BIN, LMC6682BIM, LMC6682AIN Datasheet (NSC)

LMC6681 Single/LMC6682 Dual/LMC6684 Quad
Low Voltage, Rail-To-Rail Input and Output CMOS
Amplifier with Powerdown

May 1995

LMC6681 Single/LMC6682 Dual/LMC6684 Quad Low Voltage, Rail-To-Rail Input and Output CMOS

Amplifier with Powerdown

General Description

The LMC6681/2/4 is a high performance operational ampli­fier which can operate over a wide range of supply voltages,
with guaranteed specifications at 1.8V, 2.2V, 3V, 5V, and
10V.

The LMC6681/2/4 provides an input common-mode voltage
range that exceeds both supplies. The rail-to-rail output
swing of the amplifier assures maximum dynamic signal
range. This rail-to-rail performance of the amplifier, com­bined with its high open-loop voltage gain makes it unique
among CMOS rail-to-rail amplifiers. The LMC6681/2/4 is an
excellent choice for circuits where the common-mode volt­age range is a concern.

The LMC6681/2/4 has a powerdown mode which can be
controlled externally. In this powerdown mode, the supply
current decreases from 700 µA per amplifier to less than 1
µA per amplifier. The LMC6684 has two powerdown options.
Each of the powerdown pins disables two amplifiers.

The LMC6681/2/4 has been designed specifically to improve
system performance in low voltage applications. The ampli­fier’s 80 fA input current, 0.5 mV offset voltage, and 82 dB
CMRR maintain accuracy in battery-powered systems.

Connection Diagrams

8-Pin DIP/SO

Features

(Typical unless otherwise noted)

n Guaranteed Specs at 1.8V, 2.2V, 3V, 5V, 10V
n Rail-to-Rail Input Common-Mode Voltage Range
n Rail-to-Rail Output Swing

(within 10 mV of supply rail,

n Powerdown Mode I

(Guaranteed at V

n Ultra Low Input Current 80 fA
n High Voltage Gain (V
n Unity Gain Bandwidth 1.2 MHz

S OFF

=

1.8V, 2.2V, 3V, and 5V)

S

=

S

=

@

V

3V and R

S

≤ 1.5 µA/Amplifier

=

3V, R

10 kΩ): 120 dB

L

L

Applications

n Battery Operated Circuits
n Sensor Amplifiers
n Portable Communication Devices
n Medical Instrumentation
n Battery Monitoring Circuits
n Level Detectors, Sample-and-Hold Circuits

14-Pin DIP/SO

=

10 kΩ)

DS012042-1

Top View

Top View

16-Pin DIP/SO

DS012042-3

Top View

© 1999 National Semiconductor Corporation DS012042 www.national.com

DS012042-2

Ordering Information

Package Temperature Range NSC Transport

8-Pin Molded DIP LMC6681AIN, LMC6681BIN N08E Rails
8-Pin Small Outline LMC6681AIM, LMC6681BIM M08A Rails

14-Pin Molded DIP LMC6682AIN, LMC6682BIN N14A Rails
14-Pin Small Outline LMC6682AIM, LMC6682BIM M14A Rails

16-Pin Molded DIP LMC6684AIN, LMC6684BIN N16A Rails
16-Pin Small Outline LMC6684AIM, LMC6684BIM M16A Rails

Industrial, −40˚C to +85˚C Drawing Media

LMC6681AIMX, LMC6681B1MX M08A Tape and Reel

LMC6682AIMX, LMC6682BIMX M14A Tape and Reel

LMC6684AIMX, LMC6684BIMX M16A Tape and Reel

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) 2 kV

±

Differential Input Voltage
Voltage at Input/Output Pin (V
Supply Voltage (V

+

− V−) 12V
Current at Input Pin (Note 11)
Current at Output Pin (Note 3)

Supply Voltage

+

) +0.3V, (V−) −0.3V

±

5mA

±

30 mA
Current at Power Supply Pin 35 mA
Lead Temp. (soldering, 10 sec.) 260˚C
Storage Temperature Range −65˚C to +150˚C
Junction Temperature (Note 4) 150˚C

3V DC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T
1MΩ.Boldface limits apply at the temperature extremes (Note 16).

J

=

25˚C, V

Operating Ratings (Note 1)

Supply Voltage 1.8V ≤ V
Junction Temperature Range

LMC6681AI, LMC6681BI −40˚C ≤ T
LMC6682AI, LMC6682BI −40˚C ≤ T
LMC6684AI, LMC6684BI −40˚C ≤ T

Thermal Resistance (θ

N Package, 8-pin Molded DIP 108˚C/W
M Package, 8-pin Surface Mount 172˚C/W
N Package, 14-pin Molded DIP 88˚C/W
M Package, 14-pin Surface Mount 126˚C/W
N Package, 16-pin Molded DIP 83˚C/W
M Package, 16-pin Surface Mount 114˚C/W

+

=

3.0V, V−=0V, V

)

JA

=

CM

+

=

V

V

O

/2, V

PD

=

0.6V and R

≤ 10V

S

≤ +85˚C

J

≤ +85˚C

J

≤ +85˚C

J

LMC6681AI LMC6681BI
LMC6682AI LMC6682BI
LMC6684AI LMC6684BI

Limit Limit

Units

Symbol Parameter Conditions

Typ

(Note 5)

(Note 6) (Note 6)

V

OS

Input Offset Voltage 0.5 1 3 mV

2.5 4.5 max

TCV

Input Offset Voltage 1.5 µV/˚C

OS

Average Drift

I

B

I

OS

R

IN

C

IN

Input Current (Note 12) 0.08 20 20 pA max
Input Offset Current (Note 12) 0.04 10 10 pA max
Input Resistance

>

1 Tera Ω

Input Capacitance 3 pF

CMRR Common Mode (Note 13) 82 70 65 dB

Rejection Ratio 65 62 min

PSRR Power Supply

Rejection Ratio V

V

CM

Input Common Mode CMRR>50 dB 3.23 3.18 3.18 V

±

1.5V ≤ VS≤±2.5V 82 70 65 dB

+

=

/2=V

V

O

CM

65 62 min

Voltage Range 3.00 3.00 min

−0.3 −0.18 −0.18 V

0.00 0.00 max

A

V

V

O

Large Signal
Voltage Gain

Output Swing R

=

R

600Ω (Notes 7, 12) 70 10 10 V/mV

L

=

R

10 kΩ (Notes 7, 12) 1000 12 12 V/mV

L

=

L

600Ω to V

+

/2 2.87 2.70 2.70 V

2.58 2.58 min

0.15 0.3 0.3 V

0.42 0.42 max

2kΩto V

+

/2 2.95 2.85 2.85 V

=

R

L

2.79 2.79 min

0.05 0.15 0.15 V

0.21 0.21 max

R

L

=

10 kΩ to V

+

/2 2.99 2.94 2.94 V

2.91 2.91 min

0.01 0.04 0.04 V

0.05 0.05 max

>

L

www.national.com3

3V DC Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for T
1MΩ.Boldface limits apply at the temperature extremes (Note 16).

Symbol Parameter Conditions

I

SC

Output Short Sourcing, V
Circuit Current 6.7 6.7 min

Sinking, V

I

SON

Supply Current Single, LMC6681 0.7 1.13 1.13 mA
when Powered ON V

=

1.5V 1.36 1.36 max

CM

Dual, LMC6682 1.4 2.26 2.26 mA

=

V

1.5V 2.75 2.75 max

CM

Quad, LMC6684 2.8 4.52 4.52 mA

=

V

1.5V 5.42 5.42 max

I

S OFF

Supply Current Single, LMC6681 0.5 1.5 1.5 µA
when Powered OFF V

CM

=

2.3V 2.1 2.1 max

PD

Dual, LMC6682 0.5 1.5 1.5 µA

=

V

2.3V 2.1 2.1 max

PD

Quad, LMC6684 1.0 3.0. 3.0 µA

=

V

2.3V 4.2 4.2 max

PD

=

25˚C, V

J

=

0V 20 9.0 9.0 mA

O

=

3V 12 6.0 6.0 mA

O

+

=

3.0V, V−=0V, V

Typ

(Note 5)

+

=

=

V

CM

V

O

/2, V

=

PD

0.6V and R

LMC6681AI LMC6681BI
LMC6682AI LMC6682BI
LMC6684AI LMC6684BI

Limit Limit

(Note 6) (Note 6)

4.5 4.5 min

L

Units

>

www.national.com 4

1.8V and 2.2V DC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T

@

2.2V), V

(

=

@

1.8V) and R

0.3V (

PD

>

1MΩ.Boldface limits apply at the temperature extremes (Note 16).

L

=

25˚C, V+=1.8V and 2.2V, V−=0V, V

J

CM

+

=

=

V

V

O

/2, V

=

0.4V

PD

LMC6681AI LMC6681BI

Typ LMC6682AI LMC6682BI

Symbol Parameter Conditions (Note 5) LMC6684AI LMC6684BI Units

Limit Limit

(Note 6) (Note 6)

+

V

OS

Input Offset Voltage V

=

1.8V, V

+

=

V

2.2V, V

=

1.5V 0.5 3 10 mV max

CM

=

1.5V 0.5 2 6 mV

CM

3.8 7.8 max

+

TCV

Input Offset Voltage V

OS

=

2.2V 1.5 µV/˚C

Average Drift

+

I

B

I

OS

Input Current V
Input Offset Current V

CMRR Common Mode V

Rejection Ratio V

PSRR Power Supply

Rejection Ratio V

V

CM

Input Common Mode V
Voltage Range −0.15 0.0 0.0 V max

V

O

Output Swing V

=

2.2V (Note 12) 0.08 20 20 pA max

+

=

2.2V (Note 12) 0.04 10 10 pA max

+

=

2.2V (Note 13) 82 60 60 dB min

+

=

1.8V (Note 13) 82 50 50 dB min

±

1.1V ≤ VS≤±5V, 82 70 65 dB

+

=

/2=V

V

O
+

=

CMRR

+

=

V
CMRR

+

=
=

R

L

2.2V

>

1.8V

>

CM

40 dB

40 dB

2.38 2.2 2.2 V min

1.98 1.8 1.8 V min

−0.10 0.0 0.0 V max

2.2V 2.15 2.0 2.0 V

+

2kΩto V

/2 1.88 1.88 min

65 62 min

0.05 0.2 0.2 V

0.32 0.32 max

+

=

V

1.8V 1.75 1.6 1.6 V

=

R

2kΩto V

L

+

/2 1.44 1.44 min

0.05 0.2 0.2 V

0.32 0.32 max

I

SON

Supply Current Single, LMC6681 0.7 1.1 1.1 mA
when Powered ON V

=

1.5V 1.32 1.32 max

CM

Dual, LMC6682 1.4 2.2 2.2 mA

=

V

1.5V 2.7 2.7 max

CM

Quad, LMC6684 2.8 4.4 4.4 mA

=

V

1.5V 5.3 5.3 max

I

S OFF

Supply Current Single, LMC6681 0.5 1.5 1.5 µA
when Powered OFF V

CM

=

1.5V 2.7 2.7 max

PD

Dual, LMC6682 0.5 1.5 1.5 µA

=

V

1.5V 2.7 2.7 max

PD

Quad, LMC6684 1.0 3.0 3.0 µA

=

V

1.5V 5.4 5.4 max

PD

www.national.com5

5V DC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T
1MΩ.Boldface limits apply at the temperature extremes (Note 16).

=

J

25˚C, V

+

=

5.0V, V−=0V, V

+

=

=

V

CM

V

O

/2, V

=

PD

0.9V and R

LMC6681AI LMC6681BI
LMC6682AI LMC6682BI
LMC6684AI LMC6684BI

Limit Limit

Units

Symbol Parameter Conditions

Typ

(Note 5)

(Note 6) (Note 6)

V

OS

Input Offset Voltage V

=

1.5V 0.5 1 3 mV

CM

2.5 4.5 max

TCV

OS

Input Offset Voltage 1.5 µV/˚C
Average Drift

I

B

I

OS

R

IN

C

IN

Input Current (Note 12) 0.08 20 20 pA max
Input Offset Current (Note 12) 0.04 10 10 pA max
Input Resistance

>

1 Tera Ω

Input Capacitance 3 pF

CMRR Common Mode (Note 13) 82 70 65 dB

Rejection Ratio 65 62 min

PSRR Power Supply Rejection

Ratio V

V

CM

Input Common Mode CMRR>50 dB 5.3 5.18 5.18 V

±

1.5V ≤ VS≤±2.5V 82 70 65 dB

+

=

/2=V

V

O

CM

65 62 min

Voltage Range 5.00 5.00 min

−0.3 −0.18 −0.18 V

0.00 0.00 max

V

O

Output Swing R

=

L

2kΩto V

+

/2 4.9 4.85 4.85 V

4.58 4.58 min

0.05 0.2 0.2 V

0.28 0.28 max

I

SON

Supply Current Single, LMC6681 0.8 1.24 1.24 mA
when Powered ON V

=

1.5V 1.49 1.49 max

CM

Dual, LMC6682 1.5 2.48 2.48 mA

=

V

1.5V 3.00 3.00 max

CM

Quad, LMC6684 3.0 4.96 4.96 mA

=

V

1.5V 6.00 6.00 max

I

S OFF

Supply Current Single, LMC6681 0.5 1.5 1.5 µA
when Powered OFF V

CM

=

4.3V 2.1 2.1 max

PD

Dual, LMC6682 0.5 1.5 1.5 µA

=

V

4.3V 2.1 2.1 max

PD

Quad, LMC6684 1.0 3.0 3.0 µA

=

V

4.3V 4.2 4.2 max

PD

>

L

www.national.com 6

10V DC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T

>

1MΩ.Boldface limits apply at the temperature extremes (Note 16).

=

J

25˚C, V

+

=

10.0V, V−=0V, V

+

=

=

V

CM

V

O

/2, V

PD

=

1.2V and R

LMC6681AI LMC6681BI
LMC6682AI LMC6682BI
LMC6684AI LMC6684BI

Limit Limit

Units

Symbol Parameter Conditions

Typ

(Note 5)

(Note 6) (Note 6)

V

OS

Input Offset Voltage V

=

1.5V 0.5 1.5 3.5 mV

CM

3.0 5.0 max

TCV

Input Offset Voltage 1.5 µV/˚C

OS

Average Drift

I

B

I

OS

R

IN

C

IN

Input Current (Note 12) 0.08 20 20 pA max
Input Offset Current (Note 12) 0.04 10 10 pA max
Input Resistance

>

1 Tera Ω

Input Capacitance 3 pF

CMRR Common Mode (Note 13) 82 65 65 dB

Rejection Ratio 62 62 min

PSRR Positive Power Supply

Rejection Ratio V

V

CM

Input Common Mode CMRR>50 dB 10.30 10.18 10.18 V

±

1.1V ≤ VS≤±5V 82 70 65 dB

+

=

/2 65 62 min

V

O

Voltage Range 10.00 10.00 min

−0.30 −0.18 −0.18 V

0.00 0.00 max

V

O

Output Swing R

=

L

2kΩto V

+

/2 9.93 9.7 9.7 V

9.58 9.58 min

0.08 0.3 0.3 V

0.42 0.42 max

A

V

Large Signal R

=

L

2kΩto V

+

/2 Sourcing 89 25 25 V/mV

Voltage Gain (Note 12) Sinking 224 25 25 V/mV

I

SC

Output Short Circuit Sourcing, V

=

0V 65 30 30 mA

O

Current (Note 14) 22 22 min

Sinking, V

=

10V 70 30 30 mA

O

(Note 14) 22 22 min

I

SON

Supply Current Single, LMC6681 0.9 1.50 1.50 mA
when Powered ON V

=

1.5V 1.8 1.8 max

CM

Dual, LMC6682 1.6 3.00 3.00 mA

=

V

1.5V 3.6 3.6 max

CM

Quad, LMC6684 3.2 6.00 6.00 mA

=

V

1.5V 7.2 7.2 max

I

S OFF

Supply Current Single, LMC6681 0.5 5 5 µA
when Powered OFF V

CM

=

9.3V 77max

PD

Dual, LMC6682 0.5 5 5 µA

=

V

9.3V 77max

PD

Quad, LMC6684 1.0 10 10 µA

=

V

9.3V 14 14 max

PD

L

www.national.com7

Powerdown DC Threshold Characteristics

Boldface limits apply at the temperature extremes (Note 16).

Symbol Parameter Conditions

+

V

V

PD, IL

PD, IH

Powerdown Voltage Input Low (Device V
Powered ON; Amplifier meets all V
specs in the datasheet tables) V

Powerdown Voltage Input High (Device V
Powered OFF; Refer to DC Electrical V
Characteristics for I

specs) V

S OFF

=

2.2V 0.4 V

−

=

0V 0.25

+

=

3V 0.6 V

−

=

V

0V 0.45

+

=

V

5V 0.9 V

−

=

V

0V 0.75

+

=

V

10V 1.2 V

−

=

V

0V 1.05

+

=

2.2V 1.5 V

−

=

0V 1.65

+

=

3V 2.3 V

−

=

V

0V 2.45

+

=

V

5V 4.3 V

−

=

V

0V 4.45

+

=

V

10V 9.3 V

−

=

V

0V 9.45

LMC6681AI, LMC6681BI
LMC6682AI, LMC6682BI
LMC6684AI, LMC6684BI

Min Typ Max

Units

www.national.com 8

AC Electrical Characteristics

Unless otherwise specified, all limits guaranteed for T
MΩ. Boldface limits apply at the temperature extremes (Note 16).

=

J

25˚C, V

+

=

3V, V−=0V, V

=

CM

+

=

V

V

O

/2, V

=

PD

0.6V and R

>

L

LMC6681AI LMC6681BI
LMC6682AI LMC6682BI
LMC6684AI LMC6684BI

Limit Limit

Units

Symbol Parameter Conditions

Typ

(Note 5)

(Note 6) (Note 6)

t

ON

Time Delay for (Note 15) 50 200 200 µs
Device to Power ON

t

OFF

Time Delay for (Note 15) 0.5 2 2 µs
Device to Power OFF

SR Slew Rate (Note 8) 1.2 0.7 0.7

+

0.55 0.55

=

V

10V, (Note 10) 1.2 0.7 0.7

V/µs

min

0.55 0.55

GBW Gain-Bandwidth Product 1.2 MHz

φ

m

G

m

e

n

i

n

Phase Margin 50 Deg
Gain Margin 12 dB

+

Amp-to-Amp Isolation V
Input-Referred f=1 kHz

Voltage Noise V
Input-Referred f=1 kHz

=

10V (Note 9) 130 dB

32

=

0.5V

CM

0.5

Current Noise

=

T.H.D. Total Harmonic Distortion f=1 kHz, A

=

R

10 kΩ,V

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 specific performance is not guaranteed. For guaranteed specifications and the test conditions, see the electrical characteristics.

Note 2: Human body model, 1.5 kΩ in series with 100 pF.
Note 3: Applies to both single-supply and split-supply operation. Continous short circuit operationatelevatedambienttemperature can result in exceeding the maxi-

mum allowed junction temperature of 150˚C. Output current in excess of
Note 4: The maximum power dissipation is a function of T

−TA)/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: V

+

Note 8: V
negative slew rates.

Note 9: Input referred, V
Note 10: V

tive slew rates.

Note 11: Limiting input pin current is only necessary for input voltages that exceed absolute maximum input voltage ratings.
Note 12: Guaranteed limits are dictated by tester limitations and not device performance. Actual performance is reflected in the typical value.
Note 13: CMRR

−

For CMRR

Note 14: V
Note 15: The propogation delays are measured using an input waveform of f=5 Hz, and magnitude of 2.4V. Refer to Section 6.3 and

explanation.
Note 16: The V

tion tested. Limits at temperature extremes are guaranteed via correlation using temperature regression analysis methods. Refer to Section 6.2 for an overview of
the threshold voltages.

=

3V, V

0.5V. For sourcing and sinking, 0.5V ≤ V

CM

=

3V. Connected as Voltage Follower with 2V step input, and the output is measured from 15%–85%. Number specified is the slower of the positive or

+

=

+

=

10V.Connected as voltage follower with 8V step Input, and output is measured from 15%–85%. Number specified is the slower of the positive or nega-

+

,0<V

+

=

10V, V

PD

10V, and R

and CMRR−are tested, and the number indicated is the lower of the two values. For CMRR+,V+/2<V

<

V+/2 for 3V, 5V and 10V. For 1.8V and 2.2V, 0.25<V

CM

=

0.5V. For Sourcing tests, 1V ≤ V

CM

(threshold low and threshold high) limits are guaranteed at room temperature and at temperature extremes. Room temperature limits are produc-

=

L

L

J (max)

100 kΩ connected to 5V. Each amp excited in turn with 1 kHz to produce V

≤ 5V. For Sinking tests, 5V ≤ VO≤ 9V.

O

+1 0.01

V

=

2V

O

PP

±

30 mA over long term may adversely affect reliability.

, θJA, and TA. The maximum allowable power dissipation at any ambient temperature is P

≤ 2.5V.

O

=

.

2V

O

PP

<

V+for 1.8V, 2.2V, 3V, 5V, and 10V.

<

V+− 0.3.

CM

CM

Figures 14, 15

%

=

(T

D

J(max)

for a detailed

1

www.national.com9

Typical Performance Characteristics V

Supply Current per Amplifier
vs Supply Voltage

Sourcing Current

vs Output Voltage

+=3V, Single Supply, T

S

=

25˚C unless otherwise specified

A

Sinking Current
vs Output Voltage

Input Voltage Noise
vs Common-Mode Voltage

Frequency Response
vs Temperature

DS012042-40

DS012042-43

DS012042-46

∆VOSvs V

CM

Frequency Response

vs R

L

DS012042-41

DS012042-44

DS012042-47

∆VOSvs V

CM

Input Voltage Noise
vs Frequency

DS012042-42

DS012042-45

DS012042-48

www.national.com 10

Typical Performance Characteristics V

specified (Continued)

+=3V, Single Supply, T

S

=

25˚C unless otherwise

A

CMRR
vs Frequency

Crosstalk Rejection
vs Frequency

Inverting Large
Signal Pulse Response

DS012042-49

DS012042-52

Positive PSRR
vs Frequency

Slew Rate vs
Supply Voltage

Non-Inverting Small
Signal Pulse Response

DS012042-50

DS012042-53

Negative PSRR
vs Frequency

DS012042-51

Non-Inverting Large
Signal Pulse Response

DS012042-54

Inverting Small
Signal Pulse Response

DS012042-55

DS012042-56

DS012042-57

www.national.com11

Typical Performance Characteristics V

specified (Continued)

+=3V, Single Supply, T

S

=

25˚C unless otherwise

A

Stability vs
Capacitive Load

tONDelay till Active-On
after t
Powerdown Mode, V

PD OFF

in

S

=

DS012042-58

3V

DS012042-39

Stability vs

Capacitive Load

DS012042-59

Stability vs
Capacitive Load

DS012042-60

www.national.com 12

Application Information

1.0 Input Common-Mode Voltage
Range

The LMC6681/2/4 has a rail-to-rail input common-mode volt­age range.
supplies with no resulting phase inversion on the output.

FIGURE 1. An Input Signal Exceeds the LMC6681/2/4

The absolute maximum input voltage at V
beyond either supply rail at room temperature. Voltages
greatly exceeding this absolute maximum rating, as in

2

, can cause excessive current to flow in or out of the input
pins, possibly affecting reliability. The input current can be
externally limited to
in

Figure 1

shows an input voltage exceeding both

DS012042-5

Power Supply Voltages with No Output Phase

Inversion

+

=

3V is 300 mV

±

Figure 3

.

5 mA, with an input resistor, as shown

Figure

2.0 Rail-to-Rail Output

The approximated output resistance of the LMC6681/2/4 is
50Ω sourcing, and 50Ω sinking at V
output swing can be estimated as a function of load using the
calculated output resistance.

=

3V. The maximum

S

3.0 Low Voltage Operation

The LMC6682 operates at supply voltages of 2.2V and 1.8V.
These voltages represent the End of Discharge voltages of
several popular batteries. The amplifier can operate from 1
Lead-Acid or Lithium Ion battery, or 2NiMH, NiCd, or
Carbon-Zinc batteries. Nominal and End of Discharge of
Voltage of several batteries are listed below.

Battery Type Nominal Voltage End of Discharge

Voltage

NiMH 1.2V 1V
NiCd 1.2V 1V
Lead-Acid 2V 1.8V
Silver Oxide 1.6V 1.3V
Carbon-Zinc 1.5V 1.1V
Lithium 2.6V–3.6V 1.7V–2.4V

=

At V
common-mode voltage range.
age extending to both supplies and the resulting output.

2.2V, the LMC6681/2/4 has a rail-to-rail input

S

Figure 4

shows an input volt-

FIGURE 2. A±7.5V Input Signal Greatly

Exceeds the 3V Supply in

Figure 3

,

Causing No Phase Inversion Due to R

DS012042-7

FIGURE 3. Input Current Protection for

Voltages Exceeding the Supply Voltage

DS012042-6

I

DS012042-8

FIGURE 4. The Input Common-Mode Voltage

Range Extends to Both Supplies at V

=

The amplifier is operational at V
put common-mode voltage range, output swing, and CMRR
specs.

Figure 5

=

V

1.8V.

S

shows the response of the LMC6681/2/4 at

FIGURE 5. Response of the LMC6681/2/4

at V

1.8V,with guaranteed in-

S

=

1.8V

S

=

2.2V

S

DS012042-9

www.national.com13

3.0 Low Voltage Operation (Continued)

Figure 6

shows an input voltage exceeding both supplies

with no resulting phase inversion on the output.

DS012042-10

FIGURE 6. An Input Voltage Signal Exceeds

LMC6681/2/4 Power Supply Voltages of

=

V

1.8V with No Output Phase Inversion

S

4.0 Capacitive Load Tolerance

The LMC6681/2/4 can typically drive a 100 pF load with V
=

10V at unity gain without oscillating. The unity gain fol­lower is the most sensitive configuration to capacitive load.
Direct capacitive loading reduces the phase margin of
op-amps. The combination of the op-amp’s output imped­ance and the capacitive load induces phase lag. This results
in either an underdamped pulse response or oscillation.

Capacitive load compensation can be accomplished using
resistive isolation as shown in
component of the load in parallel to the capacitive compo­nent, the isolation resistor and the resistive load create a
voltage divider at the output. This introduces a DC error at
the output.

Figure 7

. If there is a resistive

FIGURE 7. Resistive Isolation

of a 350 pF Capacitive Load

Figure 8

displays the pulse response of the LMC6681 circuit

in

Figure 7

.

S

FIGURE 8. Pulse Response of the

LMC6681 Circuit in

Another circuit, shown in

Figure 9

Figure 7

, is also used to indirectly
drive capacitive loads. This circuit is an improvement to the
circuit shown

Figure 7

because it provides DC accuracy as
well as AC stability. R1 and C1 serve to counteract the loss
of phase margin by feeding the high frequency component of
the output signal back to the amplifiers inverting input,
thereby preserving phase margin in the overall feedback
loop. The values of R1 and C1 should be experimentally de­termined by the system designer for the desired pulse re­sponse. Increased capacitive drive is possible by increasing
the value of the capacitor in the feedback loop.

DS012042-11

DS012042-12

www.national.com 14

DS012042-13

FIGURE 9. The LMC6682 Compensated

to Ensure DC Accuracy and AC Stability

4.0 Capacitive Load Tolerance (Continued)

The pulse response of the circuit shown in

Figure 9

is shown in

FIGURE 10. Pulse Response of the
LMC6682 Circuit Shown in

Figure 10

.

Figure 9

DS012042-14

Application Hints

5.0 Printed-Circuit-Board Layout for High-Impedance Work

It is generally recognized that any circuit which must operate
with less than 1000 pA of leakage current requires special
layout of the PC board. When one wishes to take advantage
of the ultra-low input current of the LMC6681/2/4, typically
less than 80 fA, it is essential to have an excellent layout.
Fortunately, the techniques of obtaining low leakages are
quite simple. First, the user must not ignore the surface leak­age of the PC board, even though it may sometimes appear
acceptably low,because under conditions of high humidity or
dust or contamination, the surface leakage will be appre­ciable.

To minimize the effect of any surface leakage, lay out a ring
of foil completely surrounding the LMC6681/2/4’s inputs and
the terminals of capacitors, diodes, conductors, resistors, re­lay terminals, etc. connected to the op-amp’s inputs, as in

Figure 11

. Tohave a significant effect, guard rings should be
placed in both the top and bottom of the PC board. This PC
foil must then be connected to a voltage which is at the same
voltage as the amplifier inputs, since no leakage current can
flow between two points at the same potential. For example,
a PC board trace-to-pad resistance of 10
mally considered a very large resistance, could leak 5 pA if
the trace were a 5V bus adjacent to the pad of the input.This
would cause a 60 times degradation from the LMC6681/2/
4’s actual performance. However, if a guard ring is held
within 5 mV of the inputs, then even a resistance of 10

12

Ω, which is nor-

11

would cause only 0.05 pA of leakage current. See
for typical connections of guard rings for standard op-amp
configurations.

Ω

FIGURE 11. Example of Guard Ring in PC Board

Layout

Figure 12

DS012042-18

www.national.com15

5.0 Printed-Circuit-Board Layout
for High-Impedance Work

(Continued)

DS012042-19

Inverting Amplifier

DS012042-20

Non-Inverting Amplifier

DS012042-21

Follower

FIGURE 12. Typical Connections of Guard Rings

The designer should be aware that when it is inappropriate
to lay out a PC board for the sake of just a few circuits, there
is another technique which is even better than a guard ring
on a PC board: Don’t insert the amplifier’s input pin into the
board at all, but bend it up in the air and use only air as an in­sulator. Air is an excellent insulator. In this case you may
have to forego some of the advantages of PC board con­struction, but the advantages are sometimes well worth the
effort of using point-to-point up-in-the-air wiring. See

13

.

Figure

(Input pins are lifted out of PC board and soldered directly to components.
All other pins are connected to PC board.)

DS012042-22

FIGURE 13. Air Wiring

6.0 Powerdown

6.1 PINOUT FOR THE LMC6681/LMC6682/LMC6684

For the LMC6681/2/4, the input, output, and power pins are
the same as those used in the standard configuration. One
of the other pins, pin 5 in the case of the LMC6681, is used
to enable the powerdown mode. The connection diagrams
for the LMC6681/2/4 are on the front page of the datasheet.

The LMC6684 has 2 powerdown options. Each of the power­down pins disables two amplifiers. If both the powerdown
pins are pulled high, all four amplifiers will be disabled. Re­ferring to the connection diagrams on the front page of the
datasheet, Pin 5 disables amplifiers B and C and Pin 13 dis­ables amplifiers A and D.

6.2 EXPLANATION OF DATASHEET PARAMETERS

The LMC6681/2/4 is ON (meets all the datasheet specs)
when the voltage applied to the powerdown pin, V
logic low. The device is OFF when V
logic levels are indicated in the test conditions in the

is a logic high. These

PD

datasheet tables. Summarizing these numbers:

Supply Logic High [V] Logic Low [V]
Voltage at room over temp at room over temp

2.2V V
3V V
5V V

10V V

≥ 1.5 VPD≥ 1.65 VPD≤ 0.4 VPD≤ 0.25

PD

≥ 2.3 VPD≥ 2.45 VPD≤ 0.6 VPD≤ 0.45

PD

≥ 4.3 VPD≥ 4.45 VPD≤ 0.9 VPD≤ 0.75

PD

≥ 9.3 VPD≥ 9.45 VPD≤ 1.2 VPD≤ 1.05

PD

In applications where the powerdown pin is not connected
externally, it is pulled to a logic low internally through a cur­rent source. The t
same for a V
LMC6681/2/4 will typically be fully operational 50 µs after a

and t

ON

in the specified range. This means that the

PD

specs will essentially be the

OFF

logic low has been applied to the powerdown pin. Please
note that the frequency of V
5 Hz.

in the test circuit below is

PD

is a

PD

www.national.com 16

6.0 Powerdown (Continued)

6.3 TEST CIRCUIT TO MEASURE t

The circuit used to measure the tON, and t
powerdown operation is a voltage follower with a load of
2kΩas shown in

Figure 14

.

When the input to the powerdown pin is low, the LMC6681/
2/4 is on. Since the amplifier is connected in the voltage fol­lower configuation, the output of the circuit is −1V.When the

AND t

ON

OFF

OFF

during the

FIGURE 14. Test Circuit for tONand t

powerdown pin is pulled high, the amplifier shuts down, and
draws less than 1 µA/Amplifier. In this powerdown mode, the
output pin has high impedance, and the output of the circuit
is pulled to 0V. t
points of the trailing edges of the input waveform at the pow-

is specified as the time between the 50

ON

erdown pin, and the waveform at the output pin. Similarly,
the t

is specified as the time between the 50%points of

OFF

the leading edges of the input waveform at the powerdown
pin, and the waveform at the output pin.

DS012042-16

Measurements

OFF

%

DS012042-17

(a) t

Measurement

OFF

and t

6.4 t

ON

The tON(time delay for device to power on) the t
lay for device to power off) specs are guaranteed at a supply
voltage of 3V.The t
V

PD

DC Threshold Characteristics table for the values for a logic

OFF

and t

applied in the specified range. Refer to the Powerdown

ON

spec are independent of the

OFF

OFF

(time de-

low and a logic high.
The guaranteed spec for t

that the signal to the V
µs). Note that the V
surements is 5 Hz. The LMC6681/2/4 is ideal for DC type ap-

is 200 µs. This does not mean

ON

pin can be as high as 5 kHz (1/200

PD

frequency for the tONand t

PD

OFF

mea-

plications where the powerdown pin is controlled by low fre­quency signals.

When the LMC6681/2/4 is powered off, internal bias currents
are shutoff. There is a inherent latency in the circuit, and the
device has to power off for a certain period of time for the t
spec to apply.Refer to the figure below. t
time interval for which the device is in the powerdown mode.

PD OFF

ON

refers to the

Consider the case when the device has been powered off for
5 ms, and then the powerdown pin is pulled to a logic low.
From

Figure 16

, at room temperature, the device powers on

after 500 µs.

FIGURE 15.

DS012042-29

(b) tONMeasurement

DS012042-39

FIGURE 16. tONDelay Till Active-On after

t

in Powerdown Mode, V

PDOFF

=

3V

S

www.national.com17

7.0 Compensating for Input
Capacitance

It is quite common to use large values of feedback resis­tance with amplifiers that have ultra-low input current, like
the LMC6681/2/4. Large feedback resistors can react with
small values of input capacitance due to transducers, photo­diodes, and circuits board parasitics to reduce phase
margins.

DS012042-15

FIGURE 17. Canceling the Effect of Input Capacitance

The effect of input capacitance can be compensated for by
adding a feedback capacitor. The feedback capacitor (as in

Figure 17

), CF, is first estimated by:

Applications
Transducer Interface Circuits

A. PIEZOELECTRIC TRANSDUCERS

DS012042-24

FIGURE 18. Transducer Interface Application

The LMC6681 can be used for processing of transducer sig­nals as shown in the circuit below. The two 11 MΩ resistors
provide a path for the DC currents to ground. Since the resis­tors are bootstrapped to the output, the AC input resistance
of the LMC6681 is much higher.

or

R1C

≤

R2C

IN

which typically provides significant overcompensation.
Printed circuit board stray capacitance may be larger or

smaller than that of a breadboard, so the actual optimum
value for C
checked on the actual circuit. (Refer to the LMC660 quad
CMOS amplifier data sheet for a more detailed discussion.)

may be different. The values of CFshould be

F

F

8.0 Spice Macromodel

A Spice Macromodel is available for the LMC6681/2/4. The
model includes a simulation of:

Input common-mode voltage range

•

Frequency and transient response

•

GBW dependence on loading conditions

•

Quiescent and dynamic supply current

•

Output swing dependence on loading conditions

•

and many more characteristics as listed on the macromodel
disk.

Contact the National Semiconductor Customer Response
Center at 1-800-272-9959 to obtain an operational amplifier
spice macromodel library disk.

DS012042-36

FIGURE 19. LMC6681 Used for Signal Processing

An input current of 80 fA and a CMRR of 82 dB causes an in­significant error offset voltage at the output. The rail-to-rail
performance of the amplifier also provides the maximum dy­namic range for the transducer signals.

B. PHOTODIODE AMPLIFIERS

DS012042-26

FIGURE 20. Photodiode Amplifier

Photocells can be used in light measuring instruments. An
error offset voltage is produced at the output due to the input
current and the offset voltage of the amplifier. The LMC6682,
which can be operated off a single battery is an excellent
choice for this application with its 80 fA input current and 0.5
mV offset voltage.

www.national.com 18

Low Voltage Peak Detector

DS012042-23

FIGURE 21. Low Voltage Peak Detector

The accuracy of the peak detector is dependent on the leak­age currents of the diodes and the capacitors, and the
non-idealities of the amplifier. The parameters of the ampli­fier which can limit the performance of this circuit are (a) Fi­nite slew rate, (b) Input current, and (c) Maximum output cur­rent of the amplifier.

The input current of the amplifier causes a slow discharge of
the capacitor. This phenomenon is called “drooping”. The
LMC6682 has a typical input current of 80 fA. This would
cause the capacitor to droop at a rate of dV/dt=I
80 fA/100 pF=0.8 mV/s. Accuracy in the amplitude mea-

/C

B

surement is also maintained by an offset voltage of 0.5 mV,
and an open-loop gain of 120 dB.

Oscillators

=

→

0.74 seconds

t

2

Then,

LMC6681/2/4 as a Comparator

=

FIGURE 23. Comparator with Hysteresis

Figure 23

comparator. The hysteresis is determined by the ratio of the
two resistors. Since the supply current of the LMC6681/2/4 is
less than 1 mA, it can be used as a low power comparator,in
applications where the quiescent current is an important pa­rameter.At V
the order of t

shows the application of the LMC6681/2/4 as a

=

3V,typical propagation delays would be on

S
PHL

=

6 µs, and t

PLH

=

5 µs.

DS012042-31

DS012042-30

FIGURE 22. 1 Hz Square — Wave Oscillator

For single supply 5V operation, the output of the circuit will
swing from 0V to 5V. The voltage divider set up R
R

will cause the non-inverting input of the LMC6681/2/4 to

4

move from 1.67V (

1

⁄3of 5V) to 3.33V (2⁄3of 5V). This voltage

2,R3

and

behaves as the threshold voltage.
R

and C1determine the time constant for the circuit. The

1

frequency of oscillation, f

OSC

is

where ∆t is the time the amplifier input takes to move from

1.67V to 3.33V. The calculations are shown below.

where τ=RC=0.68 seconds

=

→

t

0.27 seconds.

1

and

Filters

DS012042-32

FIGURE 24. Wide-Band Band-Pass Filter

The filter shown in
signals. The bandpass filter has a gain of 40 dB. The two
corner frequencies, f

Figure 24

is used to process “voice-band”

and f2are calculated as

1

www.national.com19

Filters (Continued)

The LMC6681/2/4, with its rail-to-rail input common-mode
voltage range and high gain (120 dB typical, R
extremely well suited for such filter applications. The
rail-to-rail input range allows for large input signals to be pro­cessed without distortion. The high gain means that the cir­cuit can provide filtering and gain in one stage, instead of the
typical two stage filter. This implies a reduction in cost, and
savings of space and power.

This is an illustration of the conceptual use of the LMC6681/
2/4. The selectivity of the filter can be improved by increas­ing the order (number of poles) of the design.

=

L

10 kΩ)is

Battery Monitoring Circuit

Sample-and-Hold Circuits

DS012042-34

FIGURE 25. Sample-and-Hold Application

When the “Switch” is closed during the Sample Interval,
C

charges up to the value of the input signal when the

HOLD

“Switch” is open, C
the high input impedance of the LMC6681.

Errors in the “hold” voltage are caused by the input current of
the amplifier, the leakage current of the CD4066, and the
leakage current of the capacitor. While an input current of 80
fAminimizes the accumulationrate for error in this circuit, the
LMC6681’s CMRR of 82 dB allows excellent accuracy
throughout the amplifier’s rail-to-rail dynamic capture range.

retains this value as it is buffered by

HOLD

DS012042-37

FIGURE 26. Circuit Used to Sense Charging

DS012042-38

FIGURE 27. Circuit Used to Sense Discharging

The LMC6681/2/4 has been optimized for performance at
3V,and also has guaranteed specs at 1.8V and 2.2V. In por­table applications, the R
notebook, or any other computer which the battery is power-

represents the laptop/

LOAD

ing. A desired output voltage can be achieved by
manipulating the ratios of the feedback resistors. During the
charging cycle, the current flows out of the battery as shown.
While during discharge, the current is in the reverse direc­tion. Since the current can range from a few milliamperes to
amperes, the amplifier will have to sense a signal below
ground during the discharge cycle. At 3V, the LMC6681/2/4
can accept a signal up to 300 mV below ground. The
common-mode voltage range of the LMC6681/2/4, which ex­tends beyond both rails, is thus a very useful feature in this
application.

A typical offset voltage of 0.5 mV, and CMRR of 82 dB main­tain accuracy in the circuit output, while the rail-to-rail output
performance allows for a maximum signal range.

www.national.com 20

Physical Dimensions inches (millimeters) unless otherwise noted

8-Pin Small Outline Package

Order Number LMC6681AIM or LMC6681BIM

NS Package Number M08A

14-Pin Small Outline Package

Order Number LMC6682AIM or LMC6682BIM

NS Package Number M14A

www.national.com21

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

16-Pin Small Outline Package

Order Number LMC6684AIM or LMC6684BIM

NS Package Number M16A

8-Pin Molded Dual-In-Line Package

Order Number LMC6681AIN or LMC6681BIN

NS Package Number N08E

www.national.com 22

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

14-Pin Molded Dual-In-Line Package

Order Number LMC6682AIN or LMC6682BIN

NS Package Number N14A

16-Pin Molded Dual-In-Line Package

Order Number LMC6684AIN or LMC6684BIN

NS Package Number N16A

www.national.com23

Amplifier with Powerdown

Notes

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 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

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.

labeling, can be reasonably expected to result in a
significant injury to the user.

National Semiconductor
Corporation

Americas
Tel: 1-800-272-9959
Fax: 1-800-737-7018
Email: support@nsc.com

LMC6681 Single/LMC6682 Dual/LMC6684 Quad Low Voltage, Rail-To-Rail Input and Output CMOS

www.national.com

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.

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