SGM8958-2 [SGMICRO]

Low Vos, Low Noise, High Precision Zero-Drift Operational Amplifier;


型号：	SGM8958-2
厂家：	Shengbang Microelectronics Co, Ltd
描述：	Low Vos, Low Noise, High Precision Zero-Drift Operational Amplifier
文件：	总17页 (文件大小：1032K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SGM8958-1/SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

GENERAL DESCRIPTION

FEATURES

The single SGM8958-1 and dual SGM8958-2 are low

power, high precision CMOS operational amplifiers,

which can operate from 1.8V to 5.5V single supply or

from ±0.9V to ±2.75V dual power supplies, while

consuming only 165μA quiescent current per amplifier.

The SGM8958-1/2 support rail-to-rail input and output

operation. The input common mode voltage range is

from (-V_S) - 0.1V to (+V_S) + 0.1V, and the output range

is from (-V_S) + 0.005V to (+V_S) - 0.005V.

● Low Input Offset Voltage: 10μV (MAX)

● Low Noise: 0.3μV_P-Pat 0.1Hz to 10Hz

● Input Voltage Noise: 12nV/ Hz

√

● Gain-Bandwidth Product: 1.8MHz

● Slew Rate : 0.7V/μs

● Integrated EMI Filter

● Rail-to-Rail Input and Output

● Support Single or Dual Power Supplies:

1.8V to 5.5V or ±0.9V to ±2.75V

● Quiescent Current: 165μA/Amplifier (TYP)

● -40℃ to +125℃ Operating Temperature Range

● Small Packaging:

The SGM8958-1/2 are designed to provide optimal

performance in low voltage and low power systems.

They have high impedance inputs and zero-drift 10μV

(MAX) offset voltage. These specifications make

SGM8958-1 Available in Green SOT-23-5, SC70-5

and SOIC-8 Packages

SGM8958-1/2 appropriate for

wide range of

SGM8958-2 Available in Green SOIC-8 and

TDFN-3×3-8L Packages

applications requiring high precision, such as high

linearity driver of high precision ADC.

The SGM8958-1 is available in Green SOT-23-5,

SC70-5 and SOIC-8 packages. The SGM8958-2 is

available in Green SOIC-8 and TDFN-3×3-8L packages.

They are specified over -40℃ to +125℃ temperature

range.

APPLICATIONS

Industrial Equipment

Battery-Powered Equipment

Sensor Signal Conditioning

SG Micro Corp

JULY 2022 – REV. A. 2

www.sg-micro.com

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

PACKAGE/ORDERING INFORMATION

SPECIFIED

TEMPERATURE

RANGE

PACKAGE

DESCRIPTION

ORDERING

NUMBER

PACKAGE

MARKING

PACKING

OPTION

MODEL

SOT-23-5

SC70-5

SGM8958-1XN5G/TR

GGCXX

GIBXX

Tape and Reel, 3000

Tape and Reel, 2500

Tape and Reel, 4000

-40℃ to +125℃

SGM8958-1

SGM8958-1XC5G/TR

SGM8958-1XS8G/TR

SGM8958-2XS8G/TR

SGM8958-2XTDB8G/TR

SGM

89581XS8

XXXXX

SOIC-8

SGM

89582XS8

XXXXX

SOIC-8

SGM8958-2

SGM

GGDDB

XXXXX

TDFN-3×3-8L

MARKING INFORMATION

NOTE: XX = Date Code. XXXXX = Date Code and Vendor Code.

SOT-23-5/SC70-5

SOIC-8/TDFN-3×3-8L

YYY X X

X X X X X

Date Code - Month

Date Code - Year

Serial Number

Vendor Code

Date Code - Week

Date Code - Year

Green (RoHS & HSF): SG Micro Corp defines "Green" to mean Pb-Free (RoHS compatible) and free of halogen substances. If

you have additional comments or questions, please contact your SGMICRO representative directly.

ABSOLUTE MAXIMUM RATINGS

may affect reliability. Functional operation of the device at any

conditions beyond those indicated in the Recommended

Operating Conditions section is not implied.

Supply Voltage...................................................................6V

Junction Temperature.................................................+150℃

Storage Temperature Range.......................-65℃ to +150℃

Lead Temperature (Soldering, 10s)............................+260℃

ESD Susceptibility

ESD SENSITIVITY CAUTION

This integrated circuit can be damaged if ESD protections are

not considered carefully. SGMICRO recommends that all

integrated circuits be handled with appropriate precautions.

Failureto observe proper handlingand installation procedures

can cause damage. ESD damage can range from subtle

performance degradation tocomplete device failure. Precision

integrated circuits may be more susceptible to damage

because even small parametric changes could cause the

device not to meet the published specifications.

HBM.............................................................................4000V

MM.................................................................................400V

CDM ............................................................................1000V

RECOMMENDED OPERATING CONDITIONS

Specified Voltage Range ....................................1.8V to 5.5V

Operating Temperature Range.....................-40℃ to +125℃

OVERSTRESS CAUTION

DISCLAIMER

SG Micro Corp reserves the right to make any change in

Stresses beyond those listed in Absolute Maximum Ratings

may cause permanent damage to the device. Exposure to

absolute maximum rating conditions for extended periods

circuit design, or specifications without prior notice.

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

PIN CONFIGURATIONS

SGM8958-1 (TOP VIEW)

OUT

-V_S

+V_S

+IN

+V_S

-V_S

+IN

-IN

OUT

SOT-23-5

SC70-5

SGM8958-1 (TOP VIEW)

SGM8958-2 (TOP VIEW)

-IN

OUTA

-INA

+INA

-V_S

+V_S

OUT

OUTB

-INB

+INB

+IN

-V_S

NC = NO CONNECT

SOIC-8

SGM8958-2 (TOP VIEW)

OUTA

+V_S

-INA

+INA

-V_S

OUTB

-INB

-V_S

+INB

TDFN-3×3-8L

NOTE: For TDFN-3×3-8L package, exposed pad can be connected to -V_Sor left floating.

SG Micro Corp

JULY 2022

www.sg-micro.com

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

ELECTRICAL CHARACTERISTICS

(V_S= 5V, V_CM= V_S/2, V_OUT= V_S/2, and R_L= 10kΩ to V_S/2, Full = -40℃ to +125℃, typical values are at T_A= +25℃, unless

otherwise noted.)

PARAMETER

SYMBOL

CONDITIONS

TEMP

MIN

TYP

MAX

UNITS

Input Characteristics

3.5

+25℃

Full

Input Offset Voltage

V_OS

V_S= 5V

μV

Input Offset Voltage Drift

Input Bias Current

ΔV_OS/ΔT

I_B

Full

0.03

500

μV/℃

+25℃

Full

Input Offset Current

I_OS

1000

Input Common Mode Voltage Range

V_CM

(-V_S) - 0.1

108

(+V_S) + 0.1

125

136

Common Mode Rejection Ratio

CMRR (-V_S) - 0.1V < V_CM< (+V_S) + 0.1V

106

(-V_S) + 0.1V < V_OUT< (+V_S) - 0.1V,

R_L= 10kΩ

Open-Loop Voltage Gain

A_OL

116

+25℃

Output Characteristics

Output Voltage Swing from Rail

Short-Circuit Current

R_L= 10kΩ

+25℃

I_SC

Capacitive Load Drive

Power Supply

See Typical Performance Characteristics

Specified Voltage Range

V_S

Full

+25℃

Full

1.8

5.5

Power Supply Rejection Ratio

Quiescent Current/Amplifier

PSRR V_S= 1.8V to 5.5V, V_CM= 0.2V

μV/V

165

158

250

290

+25℃

Full

I_Q

I_OUT= 0A

μA

Turn-On Time

G = +1, V_IN= 0.1V, R_L= 10kΩ, C_L= 30pF

μs

+25℃

Dynamic Performance

Gain-Bandwidth Product

Slew Rate

GBP

C_L= 30pF

1.8

0.7

MHz

+25℃

G = +1, V_OUT= 2V_P-P, C_L= 30pF

V/μs

Noise

Input Voltage Noise

Input Voltage Noise Density

f = 0.1Hz to 10Hz

f = 1kHz

0.3

μV_P-P

+25℃

e_n

nV/√Hz

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

ELECTRICAL CHARACTERISTICS (continued)

(V_S= 1.8V, V_CM= V_S/2, V_OUT= V_S/2, and R_L= 10kΩ to V_S/2, Full = -40℃ to +125℃, typical values are at T_A= +25℃, unless

otherwise noted.)

PARAMETER

SYMBOL

CONDITIONS

TEMP

MIN

TYP

MAX

UNITS

Input Characteristics

3.5

+25℃

Full

Input Offset Voltage

V_OS

V_S= 1.8V

μV

Input Offset Voltage Drift

Input Bias Current

ΔV_OS/ΔT

I_B

Full

0.04

500

μV/℃

+25℃

Full

Input Offset Current

I_OS

1000

Input Common Mode Voltage Range

V_CM

(-V_S) - 0.1

102

(+V_S) + 0.1

118

128

Common Mode Rejection Ratio

CMRR (-V_S) - 0.1V < V_CM< (+V_S) + 0.1V

100

(-V_S) + 0.1V < V_OUT< (+V_S) - 0.1V,

R_L= 10kΩ

Open-Loop Voltage Gain

A_OL

107

+25℃

Output Characteristics

Output Voltage Swing from Rail

Short-Circuit Current

R_L= 10kΩ

+25℃

I_SC

Capacitive Load Drive

Power Supply

See Typical Performance Characteristics

Specified Voltage Range

V_S

Full

+25℃

Full

1.8

5.5

Power Supply Rejection Ratio

Quiescent Current/Amplifier

PSRR V_S= 1.8V to 5.5V, V_CM= 0.2V

μV/V

220

340

395

+25℃

Full

I_Q

I_OUT= 0A

μA

Turn-On Time

G = +1, V_IN= 0.1V, R_L= 10kΩ, C_L= 30pF

μs

+25℃

Dynamic Performance

Gain-Bandwidth Product

Slew Rate

GBP

C_L= 30pF

1.4

0.7

MHz

+25℃

G = +1, V_OUT= 1V_P-P, C_L= 30pF

V/μs

Noise

Input Voltage Noise

Input Voltage Noise Density

f = 0.1Hz to 10Hz

f = 1kHz

0.4

μV_P-P

+25℃

e_n

nV/√Hz

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

TYPICAL PERFORMANCE CHARACTERISTICS

At T_A= +25℃, unless otherwise noted.

Quiescent Current vs. Temperature

Turn-On Time

0.3

V_S= 1.8V

0.25

V_S

G = +1, R_L= 10kΩ, C_L= 30pF

0.2

0.15

0.1

0.05

V_S= 5V

V_OUT

-50

-25

100 125

Time (50μs/div)

Temperature (℃)

Positive Over-Voltage Recovery

G = -10, R_L= 10kΩ, C_L= 30pF

Negative Over-Voltage Recovery

G = -10, R_L= 10kΩ, C_L= 30pF

V_IN

V_OUT

Time (5μs/div)

Large-Signal Step Response

Small-Signal Step Response

V_S= 5V, G = +1, R_L= 10kΩ, C_L= 30pF

Time (100μs/div)

SG Micro Corp

JULY 2022

www.sg-micro.com

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

At T_A= +25℃, unless otherwise noted.

Small-Signal Overshoot vs. Load Capacitance

Settling Time vs. Closed-Loop Gain

300

250

200

150

100

G = +1

V_S= 5V, V_OUT= 100mV_P-P, R_L= 10kΩ

V_S= 1.8V

V_S= 5V

0.1%

100

1000

100

1000

Load Capacitance (pF)

Closed-Loop Gain (V/V)

CMRR vs. Frequency

PSRR vs. Frequency

120

140

120

100

V_S= 5V

110

100

PSRR+

PSRR-

0.01

0.1

100

1000 10000

0.1

100

1000

10000

Frequency (kHz)

Channel Separation vs. Frequency

V_S= 5V

Open-Loop Gain and Phase vs. Frequency

V_S= 5V

G = +1000

R_L= 10kΩ

C_L= 30pF

Open-Loop Gain

-20

-40

-45

-90

-135

-180

-60

-80

Channel A to B

-100

-120

-140

Channel B to A

Phase

-20

0.1

1000

100000

0.1

100

1000

10000

Frequency (kHz)

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

TYPICAL PERFORMANCE CHARACTERISTICS (continued)

At T_A= +25℃, unless otherwise noted.

0.1Hz to 10Hz Noise

Input Voltage Noise Density vs. Frequency

100

Continues with no 1/f (flicker) noise.

V_S= 1.8V

V_S= 5V

0.1

100

1000

10000

Time (2s/div)

Frequency (Hz)

Offset Voltage Production Distribution

7060 Samples

1 Production Lot

-8 -6 -4 -2

Offset Voltage (μV)

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

APPLICATION INFORMATION

Rail-to-Rail Input

Driving Capacitive Loads

When SGM8958-1/2 work at the power supply between

1.8V and 5.5V, the input common mode voltage range

is from (-V_S) - 0.1V to (+V_S) + 0.1V. In Figure 1, the ESD

diodes between the inputs and the power supply rails

will clamp the input voltage not to exceed the rails.

The SGM8958-1/2 are designed for unity-gain stable for

capacitive load up to 1nF. If greater capacitive load

must be driven in application, the circuit in Figure 3 can

be used. In this circuit, the IR drop voltage generated

by R_ISOis compensated by feedback loop.

+V_S

R_F

C_F

V_P

R_ISO

V_N

V_OUT

C_L

V_IN

-V_S

Figure 1. Input Equivalent Circuit

Figure 3. Circuit to Drive Heavy Capacitive Load

Input Current-Limit Protection

Power Supply Decoupling and Layout

For ESD diode clamping protection, when the current

flowing through ESD diode exceeds the maximum

rating value, the ESD diode and amplifier will be

damaged, so current-limit protection will be added in

some applications. One resistor is selected to limit the

current not to exceed the maximum rating value. In

Figure 2, a series input resistor is used to limit the input

current to less than 10mA, but the drawback of this

current-limit resistor is that it contributes thermal noise

at the amplifier input. If this resistor must be added, its

value must be selected as small as possible.

A clean and low noise power supply is very important in

amplifier circuit design, besides of input signal noise,

the power supply is one of important source of noise to

the amplifiers through +V_Sand -V_Spins. Power supply

bypassing is an effective method to clear up the noise

at power supply, and the low impedance path to ground

of decoupling capacitor will bypass the noise to GND.

In application, 10μF ceramic capacitor paralleled with

0.1μF or 0.01μF ceramic capacitor is used in Figure 4.

The ceramic capacitors should be placed as close as

possible to +V_Sand -V_Spower supply pins.

+V_S

10μF

I_OVERLOAD

10mA MAX

V_OUT

0.1μF

V_IN

V_N

V_P

V_N

V_P

V_OUT

Figure 2. Input Current-Limit Protection

10μF

-V_S(GND)

Rail-to-Rail Output

The SGM8958-1/2 support rail-to-rail output operation.

In single power supply application, for example, when

+V_S= 5V, -V_S= GND, 10kΩ load resistor is tied from

OUT pin to V_S/2, the typical output swing range is from

0.005V to 4.995V.

0.1μF

-V_S

Figure 4. Amplifier Power Supply Bypassing

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

APPLICATION INFORMATION (continued)

the input are used to increase the input impedance and

eliminate drawback of low input impedance in Figure 5.

Grounding

In low speed application, one node grounding technique

is the simplest and most effective method to eliminate

the noise generated by grounding. In high speed

application, the general method to eliminate noise is to

use a complete ground plane technique, and the whole

ground plane will help distribute heat and reduce EMI

noise pickup.

R₁

R₂

V_N

V_OUT

V_P

Reduce Input-to-Output Coupling

R₃

To reduce the input-to-output coupling, the input traces

must be placed as far away from the power supply or

output traces as possible. The sensitive trace must not

be placed in parallel with the noisy trace in same layer.

They must be placed perpendicularly in different layers

to reduce the crosstalk. These PCB layout techniques

will help to reduce unwanted positive feedback and

noise.

R₄

V_REF

Figure 6. High Input Impedance Difference Amplifier

Active Low-Pass Filter

The circuit in Figure 7 is a design example of active

low-pass filter, the DC gain is equal to -R₂/R₁and the

-3dB corner frequency is equal to 1/2πR₂C. In this design,

the filter bandwidth must be less than the bandwidth of

the amplifier, the resistor values must be selected as

low as possible to reduce ringing or oscillation generated

by the parasitic parameters in PCB layout.

Typical Application Circuits

Difference Amplifier

The circuit in Figure 5 is a design example of classical

difference amplifier. If R₄/R₃= R₂/R₁, then V_OUT= (V_P-

V_N) × R₂/R₁+ V_REF

R₂

R₁

R₂

V_N

R₁

V_OUT

R₃

V_IN

V_P

V_OUT

R₄

V_REF

R₃= R₁// R₂

Figure 5. Difference Amplifier

Figure 7. Active Low-Pass Filter

High Input Impedance Difference Amplifier

The circuit in Figure 6 is a design example of high input

impedance difference amplifier, the added amplifiers at

SG Micro Corp

www.sg-micro.com

JULY 2022

SGM8958-1

SGM8958-2

Low V_OS, Low Noise, High Precision

Zero-Drift Operational Amplifiers

REVISION HISTORY

NOTE: Page numbers for previous revisions may differ from page numbers in the current version.

JULY 2022 ‒ REV.A.1 to REV.A.2

Page

Updated Typical Performance Characteristics section.........................................................................................................................................7

MARCH 2022 ‒ REV.A to REV.A.1

Page

Updated Typical Performance Characteristics section.........................................................................................................................................7

Changes from Original (DECEMBER 2016) to REV.A

Page

Changed from product preview to production data.............................................................................................................................................All

SG Micro Corp

www.sg-micro.com

JULY 2022

PACKAGE INFORMATION

PACKAGE OUTLINE DIMENSIONS

SOT-23-5

1.90

2.59

0.99

0.95

0.69

RECOMMENDED LAND PATTERN (Unit: mm)

0.2

Dimensions

In Millimeters

Dimensions

In Inches

Symbol

MIN

MAX

1.250

0.100

1.150

0.500

0.200

3.020

1.700

2.950

MIN

MAX

0.049

0.004

0.045

0.020

0.008

0.119

0.067

0.116

1.050

0.000

1.050

0.300

0.100

2.820

1.500

2.650

0.041

0.000

0.041

0.012

0.004

0.111

0.059

0.104

0.950 BSC

1.900 BSC

0.037 BSC

0.075 BSC

0.300

0°

0.600

8°

0.012

0°

0.024

8°

NOTES:

1. Body dimensions do not include mode flash or protrusion.

2. This drawing is subject to change without notice.

SG Micro Corp

TX00033.000

www.sg-micro.com

PACKAGE INFORMATION

PACKAGE OUTLINE DIMENSIONS

SC70-5

0.65

1.9

0.75

0.4

1.3

RECOMMENDED LAND PATTERN (Unit: mm)

0.20

Dimensions

In Millimeters

Dimensions

In Inches

Symbol

MIN

MAX

1.100

0.100

1.000

0.350

0.150

2.200

1.350

2.450

MIN

MAX

0.900

0.000

0.900

0.150

0.080

2.000

1.150

2.150

0.035

0.000

0.035

0.006

0.003

0.079

0.045

0.085

0.043

0.004

0.039

0.014

0.006

0.087

0.053

0.096

0.65 TYP

1.300 BSC

0.525 REF

0.026 TYP

0.051 BSC

0.021 REF

0.260

0°

0.460

8°

0.010

0°

0.018

8°

NOTES:

1. Body dimensions do not include mode flash or protrusion.

2. This drawing is subject to change without notice.

SG Micro Corp

TX00043.000

www.sg-micro.com

PACKAGE INFORMATION

PACKAGE OUTLINE DIMENSIONS

SOIC-8

0.6

2.2

5.2

1.27

RECOMMENDED LAND PATTERN (Unit: mm)

Dimensions

In Millimeters

Dimensions

In Inches

Symbol

MIN

MAX

1.750

0.250

1.550

0.510

0.250

5.100

4.000

6.200

MIN

MAX

0.069

0.010

0.061

0.020

0.010

0.200

0.157

0.244

1.350

0.100

1.350

0.330

0.170

4.700

3.800

5.800

0.053

0.004

0.053

0.013

0.006

0.185

0.150

0.228

1.27 BSC

0.050 BSC

0.400

0°

1.270

8°

0.016

0°

0.050

8°

NOTES:

1. Body dimensions do not include mode flash or protrusion.

2. This drawing is subject to change without notice.

SG Micro Corp

TX00010.000

www.sg-micro.com

PACKAGE INFORMATION

PACKAGE OUTLINE DIMENSIONS

TDFN-3×3-8L

BOTTOM VIEW

TOP VIEW

2.3

1.5 2.725

0.675

SIDE VIEW

0.65

0.24

RECOMMENDED LAND PATTERN (Unit: mm)

Dimensions

In Millimeters

Dimensions

In Inches

Symbol

MIN

MAX

0.800

0.050

MIN

0.028

0.000

MAX

0.031

0.002

0.700

0.000

0.203 REF

0.008 REF

2.900

2.200

2.900

1.400

3.100

2.400

3.100

1.600

0.114

0.087

0.114

0.055

0.122

0.094

0.122

0.063

0.200 MIN

0.650 TYP

0.008 MIN

0.026 TYP

0.180

0.375

0.300

0.575

0.007

0.015

0.012

0.023

NOTE: This drawing is subject to change without notice.

SG Micro Corp

TX00058.000

www.sg-micro.com

PACKAGE INFORMATION

TAPE AND REEL INFORMATION

REEL DIMENSIONS

TAPE DIMENSIONS

Reel Diameter

Reel Width (W1)

DIRECTION OF FEED

NOTE: The picture is only for reference. Please make the object as the standard.

KEY PARAMETER LIST OF TAPE AND REEL

Reel Width

Reel

Diameter

Pin1

Package Type

(mm)

(mm) (mm) (mm) (mm) (mm) (mm) (mm) Quadrant

SOT-23-5

SC70-5

7″

9.5

3.20

2.25

6.40

3.35

3.20

2.55

5.40

3.35

1.40

1.20

2.10

1.13

4.0

8.0

2.0

8.0

SOIC-8

13″

12.4

12.0

TDFN-3×3-8L

SG Micro Corp

TX10000.000

www.sg-micro.com

PACKAGE INFORMATION

CARTON BOX DIMENSIONS

NOTE: The picture is only for reference. Please make the object as the standard.

KEY PARAMETER LIST OF CARTON BOX

Length

(mm)

Width

(mm)

Height

(mm)

Reel Type

Pizza/Carton

7″ (Option)

368

442

386

227

410

280

224

370

7″

13″

SG Micro Corp

www.sg-micro.com

TX20000.000

SGM8958-2 [SGMICRO]

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