Datasheet MAX4256ESA, MAX4255EUK-T, MAX4254ESD, MAX4253EUB, MAX4253ESD Datasheet (Maxim)

For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.

General Description

The MAX4249–MAX4257 low-noise, low-distortion oper­ational amplifiers offer Rail-to-Rail®outputs and single­supply operation down to 2.4V. They draw only 400µA
of quiescent supply current per amplifier while featuring
ultra-low distortion (0.0002% THD), as well as low input
voltage noise density (7.9nV/√Hz) and low input current
noise density (0.5fA/√Hz). These features make the
devices an ideal choice for portable/battery-powered
applications that require low distortion and/or low noise.

For additional power conservation, the MAX4249/
MAX4251/MAX4253/MAX4256 offer a low-power shut­down mode that reduces supply current to 0.5µA and
puts the amplifiers’ outputs into a high-impedance state.
The MAX4249–MAX4257’s outputs swing rail-to-rail and
their input common-mode voltage range includes
ground. The MAX4250–MAX4254 are unity-gain stable;
the MAX4249/MAX4255/MAX4256/MAX4257 are internal­ly compensated for gains of 10V/V or greater. The single
MAX4250/MAX4255 are available in a space-saving,
5-pin SOT23 package.

Applications

Portable/Battery-Powered Equipment
Medical Instrumentation
ADC Buffers
Digital Scales
Strain Gauges
Sensor Amplifiers
Portable Communications Devices

____________________________Features

♦ Low Input Voltage Noise Density: 7.9nV/√Hz
♦ Low Input Current Noise Density: 0.5fA/√Hz
♦ Low Distortion: 0.0002% THD (1kΩ load)
♦ 400µA Quiescent Supply Current per Amplifier
♦ Single-Supply Operation from +2.4V to +5.5V
♦ Input Common-Mode Voltage Range Includes

Ground

♦ Outputs Swing within 8mV of Rails with a 10kΩ Load
♦ 3MHz GBW Product, Unity-Gain Stable

(MAX4250–MAX4254)
22MHz GBW Product, Stable with A

V

≥ 10V/V

(MAX4249/MAX4255/MAX4256/MAX4257)

♦ Excellent DC Characteristics:

V

OS

= 70µV

I

BIAS

= 1pA

Large-Signal Voltage Gain = 116dB

♦ Low-Power Shutdown Mode:

Reduces Supply Current to 0.5µA
Places Outputs in a High-Impedance State

♦ 400pF Capacitive-Load Handling Capability
♦ Available in Space-Saving SOT23 and µMAX

Packages

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

________________________________________________________________

Maxim Integrated Products

1

19-1295; Rev 2; 4/98

PART

MAX4249ESD

MAX4249EUB -40°C to +85°C

-40°C to +85°C

TEMP. RANGE

PIN-

PACKAGE

14 SO
10 µMAX

Ordering Information

Selector Guide

Ordering Information continued at end of data sheet.

Pin Configurations and Typical Operating Circuit appear at
end of data sheet.

Rail-to-Rail is a registered trademark of Nippon Motorola Ltd.

GAIN

BANDWIDTH

(MHz)

MAX4249 22

PART

MINIMUM

STABLE

GAIN (V/V)

10

SHUTDOWN

MODE

PACKAGES

2 Yes 10-pin µMAX, 14-pin SO

NO. OF AMPLIFIERS

PER PACKAGE

MAX4250 3 1 1 — 5-pin SOT23
MAX4251 3 1 1 Yes 8-pin µMAX/SO
MAX4252 3 1 2 — 8-pin µMAX/SO
MAX4253 3 1 2 Yes 10-pin µMAX, 14-pin SO
MAX4254 3 1 4 — 14-pin SO
MAX4255 22 10 1 — 5-pin SOT23
MAX4256 22 10 1 Yes 8-pin µMAX/SO
MAX4257 22 10 2 — 8-pin µMAX/SO

SOT

TOP MARK

—
—

MAX4250EUK-T

-40°C to +85°C 5 SOT23-5 ACCI

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

2 _______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

ELECTRICAL CHARACTERISTICS

(VDD= +5V, VSS= 0V, VCM= 0V, V

OUT

= VDD/2, RLtied to VDD/2, SHDN = VDDor open, TA= -40°C to +85°C, unless otherwise

noted. Typical values are at T

A

= +25°C.) (Notes 1, 2)

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.

Power-Supply Voltage (VDDto VSS)......................+6.0V to -0.3V

Analog Input Voltage (IN_+, IN_-)....(V

DD

+ 0.3V) to (VSS- 0.3V)

SHDN Input Voltage....................................+6.0V to (V

SS

- 0.3V)

Output Short-Circuit Duration to Either Supply ..........Continuous

Continuous Power Dissipation (T

A

= +70°C)

5-Pin SOT23 (derate 7.1mW/°C above +70°C)............571mW

8-Pin µMAX (derate 4.10mW/°C above +70°C)...........330mW

8-Pin SO (derate 5.88mW/°C above +70°C)................471mW

10-Pin µMAX (derate 5.6mW/°C above +70°C)...........444mW

14-Pin SO (derate 8.33mW/°C above +70°C)..............667mW

Operating Temperature Range ...........................-40°C to +85°C

Junction Temperature......................................................+150°C

Storage Temperature Range.............................-65°C to +160°C

Lead Temperature (soldering, 10sec).............................+300°C

Normal mode

SHDN = VSSto V

DD

(Note 3)

Shutdown mode (SHDN = VSS),
V

OUT

= VSSto V

DD

V

IN+

- V

IN-

≥ 10mV,

R

L

= 10kΩ to VDD/2

VSS- 0.2V ≤ VCM≤ VDD- 1.1V

Guaranteed by CMRR test

RL= 1kΩ to VDD/2, V

OUT

= 150mV to 4.75V

(Note 4)

Shutdown mode (SHDN = VSS) (Note 1)

RL= 10kΩ to VDD/2, V

OUT

= 25mV to 4.97V

(Note 4)

VDD= 2.4V to 5.5V

CONDITIONS

pF11Input Capacitance

µA0.5 1.5IIL/I

IH

SHDN Input Current

V0.8 x V

DD

V

IH

SHDN Logic High

V0.2 x V

DD

V

IL

SHDN Logic Low

µA0.001 1.0I

LEAK

Output Leakage Current

mA68I

SC

Output Short-Circuit Current

7 20

V

IN+

- V

IN-

≥ 10mV,

R

L

= 1kΩ to VDD/2

8 25

dB

80 112

A

V

80 116

Large-Signal Voltage Gain

dB75 100PSRRPower-Supply Rejection Ratio

420 575

400

V2.4 5.5V

DD

Supply-Voltage Range

Quiescent Supply Current
per Amplifier

dB70 115CMRR

Common-Mode Rejection
Ratio

V-0.2

V

DD

-

1.1

V

CM

Input Common-Mode Voltage
Range

GΩ1000R

IN

Differential Input Resistance

pA±1 ±100I

OS

Input Offset Current

µA

0.5 1.5

I

Q

±0.07 ±0.75V

OS

mVInput Offset Voltage

pA±1 ±100I

B

Input Bias Current

UNITSMIN TYP MAXSYMBOLPARAMETER

0.3 µV/°CInput Offset Voltage Tempco

mV

47 100

V

OUT

77 200

Output Voltage Swing

VDD= 3V
VDD= 5V

VDD- V

OH

VOL- V

SS

VDD- V

OH

VOL- V

SS

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

_______________________________________________________________________________________ 3

ELECTRICAL CHARACTERISTICS (continued)

(VDD= +5V, VSS= 0V, VCM= 0V, V

OUT

= VDD/2, RLtied to VDD/2, SHDN = VDDor open, TA= -40°C to +85°C, unless otherwise

noted. Typical values are at T

A

= +25°C.) (Notes 1, 2)

Note 1: SHDN is available on the MAX4249/MAX4251/MAX4253/MAX4256 only.
Note 2: The MAX4249EUB, MAX425_EU_ specifications are 100% tested at T

A

= +25°C. Limits over the extended temperature

range are guaranteed by design, not production tested.

Note 3: Guaranteed by the Power-Supply Rejection Ratio (PSRR) test.
Note 4: Guaranteed by design.
Note 5: Lowpass filter bandwidth is 22kHz for f = 1kHz, and 80kHz for f = 20kHz. Noise floor of test equipment = 10nV/√Hz.

No sustained oscillations

f = 1kHz

MAX4250–MAX4254

f = 30kHz

f = 1kHz

f = 0.1Hz to 10Hz

MAX4249/MAX4255/MAX4256/MAX4257

f = 10Hz

CONDITIONS

pF400

0.006

0.0004

fA/√Hz

0.5i

n

Input Current Noise Density

nV/√Hz

7.9

e

n

8.9

27

Input Voltage Noise Density

3

Gain-Bandwidth Product

nVp-p760en(p-p)

Peak-to-Peak Input Noise
Voltage

MHz

22

GBW

UNITSMIN TYP MAXSYMBOLPARAMETER

MAX4250–MAX4254
MAX4249/MAX4255/MAX4256/MAX4257

0.3

Slew Rate V/µs

2.1

SR

MAX4250–MAX4254, AV= +1V/V

MAX4249/MAX4255/MAX4256/MAX4257,
A

V

= +10V/V

MAX4250–MAX4254, AV= +1V/V

74

dB

12.5

G

M

Gain Margin

10

MAX4249/MAX4255/MAX4256/MAX4257,
A

V

= +10V/V

µs

1.6

Settling Time

6.7

degrees

68

Φ

M

Phase Margin

VDD= 0V to 5V step, V

OUT

stable to 0.1% µs6t

PU

Power-Up Delay Time

MAX4250–MAX4254, AV= +1V/V,
V

OUT

= 2Vp-p, RL= 1kΩ to GND

(Note 5)

f = 1kHz
f = 20kHz

Capacitive-Load Stability

0.0012

Total Harmonic
Distortion plus Noise

MAX4249/MAX4255/MAX4256/
MAX4257, AV= +10V/V,
RF= 100kΩ, RG= 11kΩ,
V

OUT

= 4Vp-p, RL= 10kΩ to GND

(Note 5)

%THD+N

MAX4250–MAX4254
MAX4249/MAX4255/MAX4256/

MAX4257

To 0.01%,
V

OUT

= 2V step

MAX4251/MAX4253

I

VDD

= 5% of

normal operation

µst

SH

Shutdown Delay Time

0.8

V

OUT

= 2.5V,

V

OUT

settles to

0.1%

µs

8

t

EN

Enable Delay Time

f = 20kHz 0.007

f = 1kHz

MAX4251/MAX4253

3.5MAX4249/MAX4256

1.2MAX4249/MAX4256

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

4 _______________________________________________________________________________________

Typical Operating Characteristics

(VDD= +5V, VSS= 0V, VCM= V

OUT

= VDD/2, input noise floor of test equipment = 10nV/√Hz for all distortion measurements,

T

A

= +25°C, unless otherwise noted.)

0

10

5

20
15

25

30

35

40

-95

-55

-35

-75

-13

7

284969

90

110

131

152

172

192

MAX4251/MAX4256 INPUT OFFSET

VOLTAGE DISTRIBUTION

MAX4249 TOC01

VOS (µV)

NUMBER OF UNITS

400 UNITS

V

CM

= 0V

T

A

= +25°C

-250

-100

-150

-200

-50

0

50

100

150

200

250

-40 0-20 20 40 60 80

OFFSET VOLTAGE

vs. TEMPERATURE

MAX4249 TOC02

TEMPERATURE (°C)

V

OS

(µV)

VCM = 0V

-50

0

100

50

150

200

-0.5 1.50.5 2.5 3.5 4.5

INPUT OFFSET VOLTAGE vs.

COMMON-MODE INPUT VOLTAGE

MAX4249 TOC03

INPUT COMMON-MODE VOLTAGE (V)

INPUT OFFSET VOLTAGE (µV)

VDD = 3V VDD = 5V

0

0.3

0.2

0.1

0.4

0.5

0.6

0 431 2 5 6 7 8 9 10

OUTPUT VOLTAGE

vs. OUTPUT LOAD CURRENT

MAX4249 TOC04

OUTPUT LOAD CURRENT (mA)

OUTPUT VOLTAGE (V)

VDD = 3V OR 5V
V

DIFF

= ±10mV

V

OL

V

DD

- V

OH

50

70
60

100

90
80

130
120
110

140

0 10050 150 200 250

LARGE-SIGNAL VOLTAGE GAIN

vs. OUTPUT VOLTAGE SWING

MAX4249TOC07

V

OUT

SWING FROM EITHER SUPPLY (mV)

A

V

(dB)

V

DD

= 3V

R

L

REFERENCED TO GND

RL = 200kΩ

RL = 20kΩ

RL = 2kΩ

0

0.03

0.02

0.01

0.04

0.05

0.06

0.07

0.08

0.09

0.10

-40 0-20 20 6040 80

OUTPUT VOLTAGE SWING (VOH)

vs. TEMPERATURE

MAX4249 TOC05

TEMPERATURE (°C)

V

DD -

V

OH

(V)

RL = 1kΩ

RL = 10kΩ

RL = 100kΩ

0

0.02

0.01

0.03

0.04

0.05

0.06

-40 0-20 20 6040 80

OUTPUT VOLTAGE SWING (VOL)

vs. TEMPERATURE

MAX4249 TOC06

TEMPERATURE (°C)

V

OL

(V)

RL = 1kΩ

RL = 10kΩ

RL = 100kΩ

60

70

80

90

100

110

120

130

140

0 50 100 150 200 250

LARGE-SIGNAL VOLTAGE GAIN

vs. OUTPUT VOLTAGE SWING

MAX4249 TOC08

V

OUT

SWING FROM EITHER SUPPLY (mV)

A

V

(dB)

RL = 200kΩ

RL = 2kΩ

V

DD

= 3V

R

L

REFERENCED TO V

DD

RL = 20kΩ

50

70
60

100

90
80

130
120
110

140

0 10050 150 200 250

LARGE-SIGNAL VOLTAGE GAIN

vs. OUTPUT VOLTAGE SWING

MAX4249TOC09

V

OUT

SWING FROM EITHER SUPPLY (mV)

A

V

(dB)

V

DD

= 5V

R

L

REFERENCED TO GND

RL = 2kΩ

RL = 20kΩ

RL = 200kΩ

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

_______________________________________________________________________________________

5

50

80
70
60

90

100

110

120

130

140

150

0 10050 150 200 250

LARGE-SIGNAL VOLTAGE GAIN

vs. OUTPUT VOLTAGE SWING

MAX4249 TOC10

V

OUT

SWING FROM EITHER SUPPLY (mV)

A

V

(dB)

RL = 200kΩ

RL = 20kΩ

RL = 2kΩ

V

DD

= 5V

R

L

REFERENCED TO V

DD

100

110

105

115

120

125

-40 0-20 20 6040 80

LARGE-SIGNAL VOLTAGE GAIN

vs. TEMPERATURE

MAX4249 TOC11

TEMPERATURE (°C)

A

V

(dB)

RL REFERENCED T0 VDD/2
V

DD

= 5V

RL = 100kΩ
V

OUT

= 10mV

to 4.99V

RL = 10kΩ
V

OUT

= 20mV

to 4.975V

RL = 1kΩ
V

OUT

= 150mV

to 4.75V

0.373

0.374

0.375

0.376

340

380

360

400

420

440

460

-40 0-20 20 6040 80

SUPPLY CURRENT AND SHUTDOWN

SUPPLY CURRENT vs. TEMPERATURE

MAX4249 TOC12

TEMPERATURE (°C)

SHUTDOWN SUPPLY CURRENT (µA)

SUPPLY CURRENT (µA)

SHDN = V

DD

PER AMPLIFIER

SHDN = V

SS

320

340

360

380

400

420

440

0

0.1

0.2

0.3

0.4

0.5

0.6

1.8 2.82.3 3.3 3.8 4.3 4.8 5.3 5.5

SUPPLY CURRENT AND SHUTDOWN

SUPPLY CURRENT vs. SUPPLY VOLTAGE

MAX4249 TOC 13A

SUPPLY VOLTAGE (V)

SUPPLY CURRENT (µA)

SHUTDOWN SUPPLY CURRENT (µA)

PER AMPLIFIER

SHDN = V

SS

SHDN = V

DD

60

-40
100 10k 100k 1M1k 10M

MAX4250–MAX4254

GAIN AND PHASE vs. FREQUENCY

-20

-10

0

-30

MAX4249 TOC15

FREQUENCY (Hz)

GAIN (dB)

PHASE (DEGREES)

10

20

30

40

50

180

-180

-108

-72

-36

-144

0

36

72

108

144

GAIN

PHASE

VDD = 3V, 5V
R

L

= 50kΩ

C

L

= 20pF

A

V

= 1000

2000

100

0.001 0.1 10.01 5

SUPPLY CURRENT

vs. OUTPUT VOLTAGE

MAX4249 TOC13B

OUTPUT VOLTAGE (V)

SUPPLY CURRENT (µA)

1000

400

VDD = 5V

VDD = 3V

40

60

80

120

100

180

160

140

1.8 2.3 2.8 3.3 3.8 4.3 4.8 5.3

INPUT OFFSET VOLTAGE

vs. SUPPLY VOLTAGE

MAX4249 TOC14

SUPPLY VOLTAGE (V)

V

OS

(µV)

VCM = 0V
V

OUT

= VDD/2

R

L

REFERENCED TO GND

RL = 1kΩ

RL = 10kΩ

RL = 100kΩ

60

-40
100 10k 100k 1M1k 10M

MAX4249, MAX4255/MAX4256/MAX4257

GAIN AND PHASE vs. FREQUENCY

-20

-10

0

-30

MAX4249 TOC16

FREQUENCY (Hz)

GAIN (dB)

PHASE (DEGREES)

10

20

30

40

50

180

-180

-108

-72

-36

-144

0

36

72

108

144

VDD = 3V, 5V
R

L

= 50kΩ

C

L

= 20pF

A

V

= 1000

GAIN

PHASE

0

-100

-110

1 1k 10k 100k 1M10 100 10M

MAX4250–MAX4254

POWER-SUPPLY REJECTION RATIO

vs. FREQUENCY

-80

-70

-60

-90

MAX4249 TOC17

FREQUENCY (Hz)

PSRR (dB)

-50

-40

-30

-20

-10

PSRR+

VDD = 3V, 5V

PSRR-

Typical Operating Characteristics (continued)

(VDD= +5V, VSS= 0V, VCM= V

OUT

= VDD/2, input noise floor of test equipment = 10nV/√Hz for all distortion measurements,

T

A

= +25°C, unless otherwise noted.)

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

6 _______________________________________________________________________________________

Typical Operating Characteristics (continued)

(VDD= +5V, VSS= 0V, VCM= V

OUT

= VDD/2, input noise floor of test equipment = 10nV/√Hz for all distortion measurements,

T

A

= +25°C, unless otherwise noted.)

1000

0.1
1k 10k 100k 1M 10M

OUTPUT IMPEDANCE

vs. FREQUENCY

MAX4249 TOC18

FREQUENCY (Hz)

OUTPUT IMPEDANCE (Ω)

1

10

100

AV = +1 (MAX4250–MAX4254)

+10 (MAX4249/MAX4255/
MAX4256/MAX4257)

AV =

30

0

10 100 1k 10k 100k

INPUT VOLTAGE N0ISE DENSITY

vs. FREQUENCY

MAX4249 TOC19

FREQUENCY (Hz)

Vn-EQUIVALENT INPUT NOISE VOLTAGE (nV/√Hz)

5

10

15

20

25

200nV/

div

1sec/div

0.1Hz TO 10Hz p-p NOISE

MAX4249 TOC20

V

DD

= 3V OR 5V

Vp-p

NOISE

= 760nVp-p

-160

-140

-120

-100

-80

-60

-40

-20

0

10 5k 10k

15k

20k

MAX4250–MAX4254

FFT OF DISTORTION AND NOISE

MAX4249 TOC21

FREQUENCY (Hz)

AMPLITUDE (dBc)

R

LOAD

= 1kΩ

f

O

= 1kHz

A

V

= +1

V

OUT

= 2Vp-p

f

O

HD2

HD3

HD4

HD5

0.001

0.01

0.1

1

10

0 21 3

MAX4250–MAX4254

THD PLUS NOISE vs.

OUTPUT VOLTAGE SWING (V

DD

= 3V)

MAX4249 TOC24

OUTPUT VOLTAGE (Vp-p)

THD+N (%)

RL = 10kΩ

RL = 1kΩ

RL = 100kΩ

V

OUT

V

IN

R

L

100k

11k

AV = +10
V

DD

= 3V

f

O

= 3kHz

FILTER BW = 30kHz

-140

-120

-100

-80

-60

-40

-20

0

20

10 5k 10k

15k

20k

MAX4249/MAX4255/MAX4256/MAX4257

FFT OF DISTORTION AND NOISE

MAX4249 TOC22

FREQUENCY (Hz)

AMPLITUDE (dBc)

V

OUT

= 4Vp-p

f

O

= 1kHz

HD2

HD3

V

O

V

IN

10k

100k

11k

f

O

0.001

0.01

0.1

1

10

0 21 3 4 5

MAX4250–MAX4254

THD PLUS NOISE

vs. OUTPUT VOLTAGE (V

DD

= 5V)

MAX4249 TOC23

OUTPUT VOLTAGE (Vp-p)

THD+N (%)

V

O

V

IN

R

L

RL = 10kΩ

RL = 1kΩ

RL = 100kΩ

100k

11k

AV = +10
f

O

= 3kHz

FILTER BW = 30kHz

0.001

0.01

0.1

1

0 3 41 2 5

MAX4249/MAX4255/MAX4256/MAX4257

THD PLUS NOISE vs. OUTPUT VOLTAGE SWING

MAX4249 TOC25

OUTPUT VOLTAGE (Vp-p)

THD+N (%)

AV = +10

fO = 20kHz, FILTER BW = 80kHz

fO = 3kHz, FILTER BW = 30kHz

V

OUT

V

IN

R

L

100k

11k

0.0001

0.01

0.001

0.1

1

10 1k100 10k

MAX4250–MAX4254

THD PLUS NOISE vs. FREQUENCY

MAX4249 TOC26

FREQUENCY (Hz)

THD+N (%)

V

IN

V

OUT

R2

R1

AV = 100

AV = 10

AV = 1

FILTER BW= 22kHz

RL = 10kΩ TO GND

VO = 2Vp-p

R1 = 5.6kΩ, R2 = 53kΩ

R1 = 560Ω, R2 = 53kΩ

R

L

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

_______________________________________________________________________________________

7

0.001

0.01

0.1

10 1k100 10k

MAX4249/MAX4255–MAX4257
TOTAL HARMONIC DISTORTION

PLUS NOISE vs. FREQUENCY

MAX4249 TOC27

FREQUENCY (Hz)

THD PLUS NOISE (%)

AV = +100, R1 = 1kΩ

AV = +10, R1 = 11kΩ

V

DD

= 3V

V

DD

= 5V

V

DD

= 3V

V

OUT

= 2.75Vp-p

FILTER BW = 80kHz

V

DD

= 5V

100kΩ

R1

R

L

= 10kΩ

V

OUT

0.0001

0.001

0.01

0.1

10 1k100 10k

MAX4250–MAX4254

TOTAL HARMONIC DISTORTION

PLUS NOISE vs. FREQUENCY

MAX4249 TOC28

FREQUENCY (Hz)

THD PLUSE NOISE (%)

RL TO VDD/2

RL TO GND

RL TO V

DD

FILTER BW = 80kHz
A

V

= +1

R

L

= 1kΩ

V

OUT

= 2Vp-p

V

OUT

200mV/

div

1.5V

0.5V

2µs/div

MAX4250–MAX4254

LARGE-SIGNAL PULSE RESPONSE

MAX4249 TOC29

V

DD

= 3V

R

L

= 10kΩ

C

L

= 100pF

V

IN

= 1V PULSE

V

OUT

20mV/

div

0.6V

0.5V

2µs/div

MAX4250–MAX4254

SMALL-SIGNAL PULSE RESPONSE

MAX4249 TOC30

V

DD

= 3V

R

L

= 10kΩ

C

L

= 100pF

V

IN

= 100mV PULSE

V

OUT

200mV/

div

2V

1V

2µs/div

MAX4249/MAX4255/MAX4256/MAX4257

LARGE-SIGNAL PULSE RESPONSE

MAX4249 TOC31

V

DD

= 3V

R

L

= 10kΩ

C

L

= 100pF

V

IN

= 100mV PULSE

A

V

= +10

V

OUT

1.6V

50mV/div

1.5V

2µs/div

MAX4249/MAX4255/MAX4256/MAX4257

SMALL-SIGNAL PULSE RESPONSE

MAX4249 TOC32

V

DD

= 3V

R

L

= 10kΩ

C

L

= 100pF

V

IN

= 10mV PULSE

A

V

= +10

140
130

0

MAX4252/MAX4253/MAX4254

CHANNEL SEPARATION vs. FREQUENCY

MAX4249 TOC33

FREQUENCY (Hz)

CHANNEL SEPARATION (dB)

100

110

120

90
80
70

1k 100k 1M10k 10M

Typical Operating Characteristics (continued)

(VDD= +5V, VSS= 0V, VCM= V

OUT

= VDD/2, input noise floor of test equipment = 10nV/√Hz for all distortion measurements,

T

A

= +25°C, unless otherwise noted.)

_______________Detailed Description

The MAX4249–MAX4257 single-supply operational
amplifiers feature ultra-low noise and distortion while
consuming very little power. Their low distortion and
low noise make them ideal for use as preamplifiers in
wide dynamic-range applications, such as 16-bit ana­log-to-digital converters (see

Typical Operating Circuit

).
Their high input impedance and low noise are also use­ful for signal conditioning of high-impedance sources,
such as piezoelectric transducers.

These devices have true rail-to-rail output operation,
drive loads as low as 1kΩ while maintaining DC accura­cy, and can drive capacitive loads up to 400pF without
oscillation. The input common-mode voltage range
extends from VDD- 1.1V to 200mV beyond the negative
rail. The push/pull output stage maintains excellent DC
characteristics, while delivering up to ±5mA of current.

The MAX4250–MAX4254 are unity-gain stable, whereas
the MAX4249/MAX4255/MAX4256/MAX4257 have a
higher slew rate and are stable for gains ≥10V/V. The
MAX4249/ MAX4251/MAX4253/MAX4256 feature a low­power shutdown mode, which reduces the supply cur­rent to 0.5µA and disables the outputs.

Low Distortion

Many factors can affect the noise and distortion that the
device contributes to the input signal. The following
guidelines offer valuable information on the impact of
design choices on Total Harmonic Distortion (THD).

Choosing proper feedback and gain resistor values for
a particular application can be a very important factor
in reducing THD. In general, the smaller the closed­loop gain, the smaller the THD generated, especially
when driving heavy resistive loads. Large-value feed­back resistors can significantly improve distortion. The
THD of the part normally increases at approximately
20dB per decade, as a function of frequency.
Operating the device near or above the full-power
bandwidth significantly degrades distortion.

Referencing the load to either supply also improves the
part’s distortion performance, because only one of the
MOSFETs of the push/pull output stage drives the out­put. Referencing the load to mid-supply increases the
part’s distortion for a given load and feedback setting.
(See the Total Harmonic Distortion vs. Frequency graph
in the

Typical Operating Characteristics

.)

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

8 _______________________________________________________________________________________

Pin Description

Amplifier Output61 1, 91, 7 1, 7, 8, 141, 13

OUT, OUTA,

OUTB, OUTC,

OUTD

3, 73, 5 3, 5, 10, 123, 11

IN+, INA+, INB+,

INC+, IND+

Noninverting Amplifier Input33

44 114 V

SS

Negative Supply. Connect
to ground for single-supply
operation.

42

2, 82, 6 2, 6, 9, 132, 12

IN-, INA-, INB-,

INC-, IND-

5, 6— —6, 9

SHDN,

SHDNA,

SHDNB

Shutdown Input. Connect to
VDDor leave unconnected for
normal operation (amplifier(s)
enabled).

8—

108

Inverting Amplifier Input24

414 V

DD

Positive Supply75

—— —5, 7, 8, 10 N.C.

No Connection. Not internally
connected.

1, 5—

PIN

MAX4249/MAX4253

MAX4252
MAX4257

10 µMAX 14 SO

MAX4254

MAX4250
MAX4255

MAX4251
MAX4256

14 SO8 µMAX/SO5 SOT23

NAME FUNCTION

For gains ≥10V/V, the decompensated devices
(MAX4249/MAX4255/MAX4256/MAX4257) deliver the
best distortion performance, since they have a higher
slew rate and provide a higher amount of loop gain for
a given closed-loop gain setting. Capacitive loads
below 400pF do not significantly affect distortion
results. Distortion performance remains relatively con­stant over supply voltages.

Low Noise

The amplifier’s input-referred noise voltage density is
dominated by flicker noise at lower frequencies, and by
thermal noise at higher frequencies. Because the ther­mal noise contribution is affected by the parallel combi­nation of the feedback resistive network (RFRG,
Figure 1), these resistors should be reduced in cases
where the system bandwidth is large and thermal noise
is dominant. This noise-contribution factor decreases,
however, with increasing gain settings.

For example, the input noise voltage density of the cir­cuit with RF= 100kΩ, RG= 11kΩ (AV= 10V/V) is
en= 15nV/√Hz. encan be reduced to 9nV/√Hz by
choosing RF= 10kΩ, RG= 1.1kΩ (AV= 10V/V), at the
expense of greater current consumption and potentially
higher distortion. For a gain of 100V/V with RF= 100kΩ,
RG= 1.1kΩ, the enis low (9nV/√Hz).

Using a Feed-Forward

Compensation Capacitor, C

Z

The amplifier’s input capacitance is 11pF. If the resis­tance seen by the inverting input is large (feedback
network), this can introduce a pole within the amplifier’s
bandwidth, resulting in reduced phase margin.
Compensate the reduced phase margin by introducing
a feed-forward capacitor (CZ) between the inverting
input and the output (Figure 1). This effectively cancels
the pole from the inverting input of the amplifier.
Choose the value of CZas follows:

CZ≈ 11 x (RF/ RG) [pF]

In the unity-gain-stable MAX4250–MAX4254, the use
of a proper CZis most important for AV= +2V/V, and
AV= -1V/V. In the decompensated MAX4249/
MAX4255/MAX4256/MAX4257, CZis most important for
AV= ±10V/V. Figures 2a and 2b show transient
response both with and without CZ.

Using a slightly smaller CZthan suggested by the for­mula above achieves a higher bandwidth at the
expense of reduced phase and gain margin. As a gen­eral guideline, consider using CZfor cases where
RGRFis greater than 20kΩ (MAX4250–MAX4254) or
greater than 5kΩ (MAX4249/MAX4255/MAX4256/
MAX4257).

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

_______________________________________________________________________________________ 9

C

Z

R

F

V

OUT

V

IN

R

G

V

OUT

(100mV/
div)

0mV

100mV

V

IN

(50mV/
div)

2µs/div

AV = +2
R

F

= RG = 100kΩ

Figure 1. Adding Feed-Forward Compensation

Figure 2a. Pulse Response with No Feed-Forward
Compensation

100mV/
div

V

IN

0mV

100mV

V

OUT

50mV/
div

2µs/div

AV = +2
R

F

= RG = 100kΩ

C

Z

= 11pF

Figure 2b. Pulse Response with 10pF Feed-Forward
Compensation

MAX4249–MAX4257

Applications Information

The MAX4249–MAX4257 combine good driving capa­bility with ground-sensing input and rail-to-rail output
operation. With their low distortion, low noise and low
power consumption, they are ideal for use in portable
instrumentation systems and other low-power, noise­sensitive applications.

Ground-Sensing and

Rail-to-Rail Outputs

The common-mode input range of the MAX4249–
MAX4257 extends down to ground, and offers excellent
common-mode rejection. These devices are guaran­teed not to undergo phase reversal when the input is
overdriven (Figure 3).

Figure 4 showcases the true rail-to-rail output operation
of the amplifier, configured with AV= 10V/V. The output
swings to within 8mV of the supplies with a 10kΩ load,
making the devices ideal in low-supply-voltage applica­tions.

Output Loading and Stability

Even with their low quiescent current of 400µA, these
amplifiers can drive 1kΩ loads while maintaining excel­lent DC accuracy. Stability while driving heavy capaci­tive loads is another key feature.

These devices maintain stability while driving loads up
to 400pF. To drive higher capacitive loads, place a
small isolation resistor in series between the output of
the amplifier and the capacitive load (Figure 5). This
resistor improves the amplifier’s phase margin by iso­lating the capacitor from the op amp’s output.
Reference Figure 6 to select a resistance value that will
ensure a load capacitance that limits peaking to <2dB
(25%). For example, if the capacitive load is 1000pF,
the corresponding isolation resistor is 150Ω. Figure 7
shows that peaking occurs without the isolation resistor.
Figure 8 shows the unity-gain bandwidth vs. capacitive
load for the MAX4250–MAX4254.

Power Supplies and Layout

The MAX4249–MAX4257 operate from a single +2.4V
to +5.5V power supply or from dual supplies of ±1.20V
to ±2.75V. For single-supply operation, bypass the

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

10 ______________________________________________________________________________________

OV

V

OUT

4.25V

4.45V

V

IN

-200mV

0

0

20µs/div

AV = +1
V

DD

= +5V

R

L

= 10kΩ

Figure 3. Overdriven Input Showing No Phase Reversal

V

OUT

1V/
div

0V

5V

200µs/div

V

DD

= +5V

R

L

= 10kΩ

A

V

= +10

f = 1kHz

Figure 4. Rail-to-Rail Output Operation

V

OUT

V

IN

R

ISO

C

L

MAX4250
MAX4251
MAX4252
MAX4253
MAX4254

Figure 5. Capacitive-Load Driving Circuit

power supply with a 0.1µF ceramic capacitor placed
close to the VDDpin. If operating from dual supplies,
bypass each supply to ground.

Good layout improves performance by decreasing the
amount of stray capacitance and noise at the op amp’s
inputs and output. To decrease stray capacitance, min­imize PC board trace lengths and resistor leads, and
place external components close to the op amp’s pins.

TRANSISTOR COUNTS:
MAX4250/MAX4251/MAX4255/MAX4256: 170
MAX4249/MAX4252/MAX4253/MAX4257: 340
MAX4254: 680

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

______________________________________________________________________________________ 11

160
140

0

10 10,000

60

20

40

120
100

80

CAPACITIVE LOADING (pF)

R

ISO

(Ω)

1000100

SHADED AREA INDICATES
STABLE OPERATION
WITH NO NEED FOR
ISOLATION RESISTOR.

NOTE: USING AN ISOLATION RESISTOR REDUCES PEAKING.

Figure 6. Isolation Resistance vs. Capacitive Loading to
Minimize Peaking (<2dB)

25

20

0

10 10,000

15

5

10

CAPACITIVE LOAD (pF)

PEAKING (dB)

1000100

MAX4250–MAX4254 (AV = +1)
MAX4249/MAX4255–MAX4257 (A

V

= +10)

R

ISO

= 0

SHADED AREA INDICATES
STABLE OPERATION
WITH NO NEED FOR
ISOLATION RESISTOR.

Figure 7. Peaking vs. Capacitive Load

4.5

3.5

4.0

0

10 10,000

2.0

3.0

2.5

1.0

0.5

1.5

CAPACITIVE LOAD (pF)

UNITY-GAIN BANDWIDTH (MHz)

1000100

VDD = 3V

SHADED AREA INDICATES
STABLE OPERATION
WITH NO NEED FOR
ISOLATION RESISTOR.

NOTE: R

ISO

CHOSEN FOR PEAKING <2dB.

Figure 8. MAX4250–MAX4254 Unity-Gain Bandwidth vs.
Capacitive Load

Ordering Information (continued)

___________________Chip Information

—8 µMAX

8 SO-40°C to +85°C

-40°C to +85°C

—

MAX4257EUA

MAX4257ESA

—8 µMAX

8 SO-40°C to +85°C

-40°C to +85°C

—

MAX4256EUA

MAX4256ESA

ACCJ5 SOT23-5-40°C to +85°C

MAX4255EUK-T

—14 SO

14 SO-40°C to +85°C

-40°C to +85°C

—

MAX4254ESD

MAX4253ESD

—10 µMAX

8 µMAX-40°C to +85°C

-40°C to +85°C

—

MAX4253EUB

MAX4252EUA

—8 SO

8 µMAX-40°C to +85°C

-40°C to +85°C

—

MAX4252ESA

MAX4251EUA

—8 SO

PIN-

PACKAGE

TEMP. RANGE

-40°C to +85°C

SOT

TOP MARK

MAX4251ESA

PART

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

12 ______________________________________________________________________________________

Pin Configurations

V

SS

IN-IN+

1 5 V

DD

OUT

MAX4250
MAX4255

SOT23

TOP VIEW

2

3 4

OUT

N.C.V

SS

1
2

87SHDN

V

DD

IN-

IN+

N.C.

µMAX/SO

3

4

6

5

MAX4251

MAX4256

INB-

INB+V

SS

1
2

87V

DD

OUTBINA-

INA+

OUTA

µMAX/SO

3

4

6

5

MAX4252
MAX4257

1
2
3
4
5

10

9
8
7
6

V

DD

OUTB
INB­INB+V

SS

INA+

INA-

OUTA

MAX4249
MAX4253

µMAX

SHDNBSHDNA

14
13
12
11
10

9
8

1
2
3
4
5
6
7

V

DD

OUTB
INB­INB+V

SS

INA+

INA-

OUTA

MAX4249
MAX4253

N.C.
SHDNB
N.C.N.C.

SHDNA

N.C.

SO

14
13
12
11
10

9
8

1
2
3
4
5
6
7

OUTD
IND­IND+
V

SS

V

DD

INA+

INA-

OUTA

MAX4254

INC+
INC­OUTCOUTB

INB-

INB+

SO

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

______________________________________________________________________________________ 13

Typical Operating Circuit

MAX195

SERIAL
INTERFACE

DOUT

SCLK

SHDN

SHDN

AIN

V

IN

(16-BIT ADC)

REF

-5V

2

50k

+5V

3

4

6

7

8

5k

V

DD

V

SS

4.096V

CS

MAX4256

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

14 ______________________________________________________________________________________

8LUMAXD.EPS

Package Information

SOT5L.EPS

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,

Low-Distortion, Rail-to-Rail Op Amps

______________________________________________________________________________________ 15

___________________________________________Package Information (continued)

10LUMAXB.EPS

MAX4249–MAX4257

SOT23, Single-Supply, Low-Noise,
Low-Distortion, Rail-to-Rail Op Amps

Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.

16

____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600

© 1998 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.

___________________________________________Package Information (continued)

SOICN.EPS