LMV861MG/NOPB [TI]

Single, 5.5-V, 31-MHz, high output current (150-mA), low noise (8-nV/√Hz) operational amplifier | DCK | 5 | -40 to 125;


型号：	LMV861MG/NOPB
厂家：	TEXAS INSTRUMENTS
描述：	Single, 5.5-V, 31-MHz, high output current (150-mA), low noise (8-nV/√Hz) operational amplifier \| DCK \| 5 \| -40 to 125 放大器光电二极管
文件：	总31页 (文件大小：1575K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

LMV861, LMV862

www.ti.com

SNOSAZ5C –FEBRUARY 2008–REVISED MARCH 2013

LMV861/LMV862 30 MHz Low Power CMOS, EMI Hardened Operational Amplifiers

Check for Samples: LMV861, LMV862

FEATURES

DESCRIPTION

TI’s LMV861 and LMV862 are CMOS input, low

power op amp IC's, providing a low input bias current,

a wide temperature range of −40°C to +125°C and

exceptional performance making them robust general

purpose parts. Additionally, the LMV861 and LMV862

are EMI hardened to minimize any interference so

they are ideal for EMI sensitive applications.

Unless Otherwise Noted, Typical Values at T_A

= 25°C, V⁺= 3.3V

•

Supply Voltage 2.7V to 5.5V

Supply Current (per Channel) 2.25 mA

Input Offset Voltage 1 mV Max

Input Bias Current 0.1 pA

GBW 30 MHz

The unity gain stable LMV861 and LMV862 feature

30 MHz of bandwidth while consuming only 2.25 mA

of current per channel. These parts also maintain

stability for capacitive loads as large as 200 pF. The

LMV861 and LMV862 provide superior performance

and economy in terms of power and space usage.

EMIRR at 1.8 GHz 105 dB

Input Noise Voltage at 1 kHz 8 nV/√Hz

Slew Rate 18 V/µs

Output Voltage Swing Rail-to-Rail

Output Current Drive 67 mA

This family of parts has a maximum input offset

voltage of 1 mV, a rail-to-rail output stage and an

input common-mode voltage range that includes

ground. Over an operating range from 2.7V to 5.5V

the LMV861 and LMV862 provide a PSRR of 93 dB,

and a CMRR of 93 dB. The LMV861 is offered in the

space saving 5-Pin SC70 package, and the LMV862

in the 8-Pin VSSOP.

Operating Ambient Temperature Range −40°C

to 125°C

APPLICATIONS

•

Photodiode Preamp

Weight Scale Systems

Filters/Buffers

Medical Diagnosis Equipment

Typical Application

NO RF RELATED

DISTURBANCES

PRESSURE

SENSOR

ADC

EMI HARDENED

INTERFERING

RF SOURCES

Figure 1. EMI Hardened Sensor Application

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

All trademarks are the property of their respective owners.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

LMV861, LMV862

SNOSAZ5C –FEBRUARY 2008–REVISED MARCH 2013

www.ti.com

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

Absolute Maximum Ratings⁽¹⁾⁽²⁾

Human Body Model

Charge-Device Model

Machine Model

2 kV

ESD Tolerance⁽³⁾

1 kV

200V

V_INDifferential

Supply Voltage (V_S= V⁺– V⁻)

± Supply Voltage

Voltage at Input/Output Pins

V⁺+0.4V

V⁻−0.4V

Storage Temperature Range

Junction Temperature⁽⁴⁾

Soldering Information

−65°C to +150°C

+150°C

Infrared or Convection (20 sec)

260°C

(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 ensured. For ensured specifications and the test

conditions, see the Electrical Characteristics Tables.

(2) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and

specifications.

(3) Human Body Model, applicable std. MIL-STD-883, Method 3015.7. Machine Model, applicable std. JESD22-A115-A (ESD MM std. of

JEDEC) Field-Induced Charge-Device Model, applicable std. JESD22-C101-C (ESD FICDM std. of JEDEC).

(4) The maximum power dissipation is a function of T_J(MAX), θ_JAand T_A. The maximum allowable power dissipation at any ambient

temperature is P_D= (T_J(MAX)- T_A)/ θ_JA. All numbers apply for packages soldered directly onto a PC board.

Operating Ratings⁽¹⁾

Temperature Range⁽²⁾

Supply Voltage (V_S= V⁺– V⁻)

−40°C to +125°C

2.7V to 5.5V

302°C/W

(2)

Package Thermal Resistance (θ_JA

)

5-Pin SC70

8-Pin VSSOP

217°C/W

(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 ensured. For ensured specifications and the test

conditions, see the Electrical Characteristics Tables.

(2) The maximum power dissipation is a function of T_J(MAX), θ_JAand T_A. The maximum allowable power dissipation at any ambient

temperature is P_D= (T_J(MAX)- T_A)/ θ_JA. All numbers apply for packages soldered directly onto a PC board.

3.3V Electrical Characteristics⁽¹⁾

Unless otherwise specified, all limits are guaranteed for T_A= 25°C, V⁺= 3.3V, V⁻= 0V, V_CM= V⁺/2, and R_L=10 kΩ to V⁺/2.

Boldface limits apply at the temperature extremes.

Symbol

Parameter

Input Offset Voltage⁽⁴⁾

Conditions

Min⁽²⁾

Typ⁽³⁾

Max⁽²⁾

Units

V_OS

±273

±1000

1260

μV

TCV_OSInput Offset Voltage Temperature

Drift⁽⁴⁾⁽⁵⁾

±0.7

0.1

±2.6

μV/°C

I_B

Input Bias Current⁽⁵⁾

500

I_OS

Input Offset Current

(1) Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very

limited self-heating of the device such that T_J= T_A. No assurance of parametric performance is indicated in the electrical tables under

conditions of internal self-heating where T_J> T_A.

(2) Limits are 100% production tested at 25°C. Limits over the operating temperature range are ensured through correlations using

statistical quality control (SQC) method.

(3) Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary

over time and will also depend on the application and configuration. The typical values are not tested and are not ensured on shipped

production material.

(4) The typical value is calculated by applying absolute value transform to the distribution, then taking the statistical average of the resulting

distribution

(5) This parameter is specified by design and/or characterization and is not tested in production.

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LMV861, LMV862

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SNOSAZ5C –FEBRUARY 2008–REVISED MARCH 2013

3.3V Electrical Characteristics⁽¹⁾(continued)

Unless otherwise specified, all limits are guaranteed for T_A= 25°C, V⁺= 3.3V, V⁻= 0V, V_CM= V⁺/2, and R_L=10 kΩ to V⁺/2.

Boldface limits apply at the temperature extremes.

Symbol

Parameter

Conditions

0.2V ≤ V_CM≤ V⁺- 1.2V

Min⁽²⁾

Typ⁽³⁾

Max⁽²⁾

Units

CMRR Common-Mode Rejection Ratio⁽⁴⁾

PSRR

Power Supply Rejection Ratio⁽⁴⁾

2.7V ≤ V⁺≤ 5.5V,

V_OUT= 1V

EMIRR EMI Rejection Ratio, IN+ and IN−⁽⁶⁾

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 400 MHz

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 900 MHz

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 1800 MHz

105

110

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 2400 MHz

CMVR Input Common-Mode Voltage Range

CMRR ≥ 65 dB

−0.1

2.1

A_VOL

Large Signal Voltage Gain⁽⁷⁾

R_L= 2 kΩ

V_OUT= 0.15V to 1.65V,

V_OUT= 3.15V to 1.65V

100

110

113

R_L= 10 kΩ

100

V_OUT= 0.1V to 1.65V,

V_OUT= 3.2V to 1.65V

V_OUT

Output Voltage Swing High

LMV861,

R_L= 2 kΩ to V⁺/2

LMV862,

R_L= 2 kΩ to V⁺/2

LMV861,

R_L= 10 kΩ to V⁺/2

LMV862,

R_L= 10 kΩ to V⁺/2

mV from

either rail

Output Voltage Swing Low

LMV861,

R_L= 2 kΩ to V⁺/2

LMV862,

R_L= 2 kΩ to V⁺/2

LMV861,

R_L= 10 kΩ to V⁺/2

LMV862,

R_L= 10 kΩ to V⁺/2

I_OUT

Output Short Circuit Current

Supply Current

Sourcing, V_OUT= V_CM

V_IN= 100 mV

2.25

4.42

Sinking, V_OUT= V_CM

V_IN= −100 mV

I_S

LMV861

2.59

3.00

LMV862

5.02

5.77

Slew Rate⁽⁸⁾

A_V= +1, V_OUT= 1 V_PP

V/μs

10% to 90%

GBW

Φ_m

Gain Bandwidth Product

Phase Margin

MHz

deg

e_n

Input Referred Voltage Noise Density

f = 1 kHz

f = 100 kHz

f = 1 kHz

nV/√Hz

pA/√Hz

i_n

Input Referred Current Noise Density

0.015

(6) The EMI Rejection Ratio is defined as EMIRR = 20log ( V_{RF_PEAK}/ΔV_OS).

(7) The specified limits represent the lower of the measured values for each output range condition.

(8) Number specified is the slower of positive and negative slew rates.

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3.3V Electrical Characteristics⁽¹⁾(continued)

Unless otherwise specified, all limits are guaranteed for T_A= 25°C, V⁺= 3.3V, V⁻= 0V, V_CM= V⁺/2, and R_L=10 kΩ to V⁺/2.

Boldface limits apply at the temperature extremes.

Symbol

R_OUT

C_IN

Parameter

Conditions

Min⁽²⁾

Typ⁽³⁾

Max⁽²⁾

Units

Closed Loop Output Impedance

Common-Mode Input Capacitance

Differential-Mode Input Capacitance

f = 20 MHz

Ω

THD+N Total Harmonic Distortion + Noise

f = 1 kHz, A_V= 1, BW ≥ 500 kHz

0.02

5V Electrical Characteristics⁽¹⁾

Unless otherwise specified, all limits are ensured for T = 25°C, V⁺= 5V, V⁻= 0V, V_CM= V⁺/2, and R_L=10 kΩ to V⁺/2.

Boldface limits apply at the temperature extremes.

Symbol

Parameter

Input Offset Voltage⁽⁴⁾

Conditions

Min⁽²⁾

Typ⁽³⁾

Max⁽²⁾

Units

μV

V_OS

±273

±1000

1260

TCV_OSInput Offset Voltage Temperature

Drift⁽⁴⁾⁽⁵⁾

±0.7

0.1

±2.6

μV/°C

I_B

Input Bias Current⁽⁵⁾

500

I_OS

Input Offset Current

CMRR Common-Mode Rejection Ratio⁽⁴⁾

0V ≤ V_CM≤ V⁺–1.2V

PSRR

Power Supply Rejection Ratio⁽⁴⁾

2.7V ≤ V⁺≤ 5.5V,

V_OUT= 1V

EMIRR EMI Rejection Ratio, IN+ and IN−⁽⁶⁾

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 400 MHz

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 900 MHz

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 1800 MHz

105

110

V_{RF_PEAK}= 100 mV_P(−20 dBV_P),

f = 2400 MHz

CMVR Input Common-Mode Voltage Range

CMRR ≥ 65 dB

−0.1

3.9

A_VOL

Large Signal Voltage Gain⁽⁷⁾

R_L= 2 kΩ

V_OUT= 0.15V to 2.5V,

V_OUT= 4.85V to 2.5V

103

100

111

113

R_L= 10 kΩ

103

V_OUT= 0.1V to 2.5V,

V_OUT= 4.9V to 2.5V

100

(1) Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very

limited self-heating of the device such that T_J= T_A. No assurance of parametric performance is indicated in the electrical tables under

conditions of internal self-heating where T_J> T_A.

(2) Limits are 100% production tested at 25°C. Limits over the operating temperature range are ensured through correlations using

statistical quality control (SQC) method.

(3) Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary

over time and will also depend on the application and configuration. The typical values are not tested and are not ensured on shipped

production material.

(4) The typical value is calculated by applying absolute value transform to the distribution, then taking the statistical average of the resulting

distribution

(5) This parameter is specified by design and/or characterization and is not tested in production.

(6) The EMI Rejection Ratio is defined as EMIRR = 20log ( V_{RF_PEAK}/ΔV_OS).

(7) The specified limits represent the lower of the measured values for each output range condition.

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Product Folder Links: LMV861 LMV862

LMV861, LMV862

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SNOSAZ5C –FEBRUARY 2008–REVISED MARCH 2013

5V Electrical Characteristics⁽¹⁾(continued)

Unless otherwise specified, all limits are ensured for T = 25°C, V⁺= 5V, V⁻= 0V, V_CM= V⁺/2, and R_L=10 kΩ to V⁺/2.

Boldface limits apply at the temperature extremes.

Symbol

Parameter

Conditions

Min⁽²⁾

Typ⁽³⁾

Max⁽²⁾

Units

V_OUT

Output Voltage Swing High,

LMV861,

R_L= 2 kΩ to V⁺/2

LMV862,

R_L= 2 kΩ to V⁺/2

LMV861,

R_L= 10 kΩ to V⁺/2

LMV862,

R_L= 10 kΩ to V⁺/2

mV from

either rail

Output Voltage Swing Low,

LMV861,

R_L= 2 kΩ to V⁺/2

LMV862,

R_L= 2 kΩ to V⁺/2

LMV861,

R_L= 10 kΩ to V⁺/2

LMV862,

R_L= 10 kΩ to V⁺/2

I_OUT

Output Short Circuit Current

Supply Current

Sourcing, V_OUT= V_CM

V_IN= 100 mV

150

2.47

4.85

Sinking, V_OUT= V_CM

V_IN= −100 mV

I_S

LMV861

2.84

3.27

LMV862

5.63

6.35

Slew Rate⁽⁸⁾

A_V= +1, V_OUT= 2V_PP

V/μs

10% to 90%

GBW

Φ_m

Gain Bandwidth Product

Phase Margin

MHz

deg

e_n

Input Referred Voltage Noise Density

f = 1 kHz

nV/√Hz

f = 100 kHz

f = 1 kHz

i_n

Input Referred Current Noise Density

Closed Loop Output Impedance

Common-Mode Input Capacitance

Differential-Input Capacitance

0.015

pA/√Hz

R_OUT

C_IN

f = 20 MHz

Ω

THD+N Total Harmonic Distortion + Noise

f = 1 kHz, A_V= 1, BW ≥ 500 kHz

0.02

(8) Number specified is the slower of positive and negative slew rates.

Connection Diagram

Figure 2. 5-Pin SC70

(Top View)

Figure 3. 8-Pin VSSOP

(Top View)

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Typical Performance Characteristics

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

V_OSvs. V_CMat V⁺= 3.3V

V_OSvs. V_CMat V⁺= 5.0V

0.3

0.2

0.1

0.3

0.2

0.1

-40°C

25°C

-40°C

25°C

-0.1

-0.2

-0.3

-0.1

-0.2

-0.3

85°C

125°C

= 5.0V

0.5

= 3.3V

-0.5 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

(V)

-0.5

1.5

2.5

(V)

3.5

4.5

5.5

Figure 4.

Figure 5.

V_OSvs. Supply Voltage

V_OSvs. Temperature

0.3

0.2

0.1

200

150

100

-40°C

3.3V

-50

-0.1

-0.2

-0.3

25°C

85°C

-100

-150

-200

5.0V

125°C

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

-50 -25

75 100 125

(V)

TEMPERATURE (°C)

SUPPLY

Figure 6.

Figure 7.

V_OSvs. V_OUT

Input Bias Current vs. V_CMat 25°C

= 25°C

= 5.0V, R = 2k

-1

-2

-3

-4

-5

-3

-6

-9

-12

3.3V

-1

(V)

OUT

(V)

Figure 8.

Figure 9.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

Input Bias Current vs. V_CMat 85°C

Input Bias Current vs. V_CMat 125°C

= 125°C

= 85°C

500

400

300

200

100

5.0V

-10

-20

-30

-40

-50

-100

-200

-300

-400

-500

5.0V

3.3V

-1

(V)

Figure 10.

Figure 11.

Supply Current vs. Supply Voltage Single LMV861

Supply Current vs. Supply Voltage Dual LMV862

3.4

6.0

125°C

85°C

3.2

5.5

5.0

125°C

3.0

85°C

2.8

2.6

2.4

4.5

25°C

2.2

4.0

-40°C

2.0

-40°C

3.5

1.8

1.6

3.0

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

Figure 12.

Figure 13.

Supply Current vs. Temperature Single LMV861

Supply Current vs. Temperature Dual LMV862

3.2

6.5

3.0

6.0

2.8

5.0V

5.5

5.0V

2.6

2.4

5.0

4.5

2.2

3.3V

4.0

3.5

3.0

2.0

1.8

1.6

-50 -25

75 100 125

-50 -25

75 100 125

TEMPERATURE (°C)

Figure 14.

Figure 15.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

Sinking Current vs. Supply Voltage

Sourcing Current vs. Supply Voltage

250

200

250

200

150

100

25°C

-40°C

25°C

-40°C

150

100

125°C

85°C

85°C 125°C

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

Figure 16.

Figure 17.

Output Swing High vs. Supply Voltage R_L= 2 kΩ

Output Swing High vs. Supply Voltage R_L= 10 kΩ

= 2k

= 10k

125°C

85°C

25°C

-40°C

25°C

-40°C

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

Figure 18.

Figure 19.

Output Swing Low vs. Supply Voltage R_L= 2 kΩ

Output Swing Low vs. Supply Voltage R_L= 10 kΩ

= 10k

= 2k

125°C

25°C

85°C

125°C

25°C

85°C

-40°C

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

Figure 20.

Figure 21.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

Output Voltage Swing vs. Load Current at V⁺= 3.3V

Output Voltage Swing vs. Load Current at V⁺= 5.0V

SINK

125°C

1.0

0.8

0.6

0.4

0.2

0.8

0.6

0.4

0.2

-40°C

V = 5.0V

= 3.3V

-40°C

-0.2

-0.4

-0.6

-0.8

-1.0

-0.2

-0.4

-0.6

-0.8

-1.0

125°C

SOURCE

10 20 30 40 50 60 70 80

(mA)

10 20 30 40 50 60 70 80

(mA)

LOAD

Figure 22.

Figure 23.

Open Loop Frequency Response vs. Temperature

Open Loop Frequency Response vs. Load Conditions

25°C

85°C

125°C

20 pF

120

105

120

105

PHASE

5 pF

GAIN

100 pF

50 pF

GAIN

-40°C

25°C

85°C

125°C

= 5 pF

5 pF

= 20 pF

= 50 pF

= 100 pF

-40°C

= 5 pF

100 pF

10M

10k

100k

100M

10k

100k

10M

100M

FREQUENCY (Hz)

Figure 24.

Figure 25.

Phase Margin vs. Capacitive Load

PSRR vs. Frequency

120

100

3.3V

5.0V

-PSRR

3.3V

5.0V

+PSRR

100k

= 3.3V, 5.0V

100

(pF)

1000

100

10k

10M

FREQUENCY (Hz)

LOAD

Figure 26.

Figure 27.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

CMRR vs. Frequency

Channel Separation vs. Frequency

AC CMRR

100

160

140

120

100

DC CMRR

= 3.3V, 5.0V

10k

= 3.3V, 5.0V

100

10k

100k

10M

100k

10M

FREQUENCY (Hz)

Figure 28.

Figure 29.

Large Signal Step Response with Gain = 1

Large Signal Step Response with Gain = 10

f = 1 MHz

= +1

= +10

= 500 mV

= 100 mV

100 ns/DIV

Figure 30.

Figure 31.

Small Signal Step Response with Gain = 1

Small Signal Step Response with Gain = 10

f = 1 MHz

= +1

= +10

= 100 mV

= 10 mV

100 ns/DIV

Figure 32.

Figure 33.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

Slew Rate vs. Supply Voltage

Input Voltage Noise vs. Frequency

100

FALLING EDGE

RISING EDGE

= +1

= 5 pF

= 3.3V, 5.0V

100

2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0

10k

100k

FREQUENCY (Hz)

SUPPLY VOLTAGE (V)

Figure 34.

Figure 35.

THD+N vs. Frequency

THD+N vs. Amplitude

BW = >500 kHz

= 5.0V

0.1

0.01

= 10x

= 3.3V

= 10x

V =3.3V, V =320 mV

V⁺=5.0V, V_IN=480 mV_PP

V⁺=3.3V, V_IN=2.3 V_PP

= 1x

0.1

0.001

0.0001

0.01

0.001

V =5.0V, V =3.8 V

IN PP

= 1x

f = 1 kHz

BW = >500 kHz

100

10k

100k

1m 10m

100m

)

OUT PP

FREQUENCY (Hz)

Figure 36.

Figure 37.

R_OUTvs. Frequency

EMIRR IN+ vs. Power at 400 MHz

100

120

110

100

= 100x

125°C

85°C

0.1

= 10x

100k

25°C

0.01

-40°C

= 1x

= 400 MHz

0.001

-40

100

10k

10M

-30

-20

-10

FREQUENCY (Hz)

RF INPUT PEAK VOLTAGE (dBVp)

Figure 38.

Figure 39.

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Typical Performance Characteristics (continued)

At T_A= 25°C. R_L= 10 kΩ, V⁺= 3.3V, V⁻= 0V, unless otherwise specified.

EMIRR IN+ vs. Power at 900 MHz

EMIRR IN+ vs. Power at 1800 MHz

120

110

100

125°C

85°C

110

100

125°C

85°C

25°C

-40°C

25°C

-40°C

= 900 MHz

-30

= 1800 MHz

-40

-20

-10

-30

-20

-10

RF INPUT PEAK VOLTAGE (dBVp)

Figure 40.

Figure 41.

EMIRR IN+ vs. Power at 2400 MHz

EMIRR IN+ vs. Frequency

120

110

100

125°C

85°C

120

110

100

125°C

85°C

25°C

-40°C

25°C

-40°C

= 3.3V, 5.0V

= -20 dBVp

RF PEAK

V_PEAK= -20dBVp

= 2400 MHz

-40

-30

-20

-10

100

1000

10000

FREQUENCY (MHz)

RF INPUT PEAK VOLTAGE (dBVp)

Figure 42.

Figure 43.

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APPLICATION INFORMATION

INTRODUCTION

The LMV861 and LMV862 are operational amplifiers with excellent specifications, such as low offset, low noise

and a rail-to-rail output. These specifications make the LMV861 and LMV862 great choices for medical and

instrumentation applications such as diagnosis equipment and power line monitors. The low supply current is

perfect for battery powered equipment. The small packages, SC70 package for the LMV861, and the VSSOP

package for the dual LMV862, make these parts a perfect choice for portable electronics. Additionally, the EMI

hardening makes the LMV861 and LMV862 a must for almost all op amp applications. Most applications are

exposed to Radio Frequency (RF) signals such as the signals transmitted by mobile phones or wireless

computer peripherals. The LMV861 and LMV862 will effectively reduce disturbances caused by RF signals to a

level that will be hardly noticeable. This again reduces the need for additional filtering and shielding. Using this

EMI resistant series of op amps will thus reduce the number of components and space needed for applications

that are affected by EMI, and will help applications, not yet identified as possible EMI sensitive, to be more robust

for EMI.

INPUT CHARACTERISTICS

The input common mode voltage range of the LMV861 and LMV862 includes ground, and can even sense well

below ground. The CMRR level does not degrade for input levels up to 1.2V below the supply voltage. For a

supply voltage of 5V, the maximum voltage that should be applied to the input for best CMRR performance is

thus 3.8V.

When not configured as unity gain, this input limitation will usually not degrade the effective signal range. The

output is rail-to-rail and therefore will introduce no limitations to the signal range.

The typical offset is only 0.273 mV, and the TCV_OSis 0.7 μV/°C, specifications close to precision op amps.

CMRR MEASUREMENT

The CMRR measurement results may need some clarification. This is because different setups are used to

measure the AC CMRR and the DC CMRR.

The DC CMRR is derived from ΔV_OSversus ΔV_CM. This value is stated in the tables, and is tested during

production testing. The AC CMRR is measured with the test circuit shown in Figure 44.

1 kW

BUFFER

1 kW

Buffer

OUT

LMV86x

R11

1 kW

BUFFER

R12

995W

10W

Figure 44. AC CMRR Measurement Setup

The configuration is largely the usually applied balanced configuration. With potentiometer P1, the balance can

be tuned to compensate for the DC offset in the DUT. The main difference is the addition of the buffer. This

buffer prevents the open-loop output impedance of the DUT from affecting the balance of the feedback network.

Now the closed-loop output impedance of the buffer is a part of the balance. But as the closed-loop output

impedance is much lower, and by careful selection of the buffer also has a larger bandwidth, the total effect is

that the CMRR of the DUT can be measured much more accurately. The differences are apparent in the larger

measured bandwidth of the AC CMRR.

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One artifact from this test circuit is that the low frequency CMRR results appear higher than expected. This is

because in the AC CMRR test circuit the potentiometer is used to compensate for the DC mismatches. So,

mainly AC mismatch is all that remains. Therefore, the obtained DC CMRR from this AC CMRR test circuit tends

to be higher than the actual DC CMRR based on DC measurements.

The CMRR curve in Figure 45 shows a combination of the AC CMRR and the DC CMRR.

AC CMRR

100

DC CMRR

= 3.3V, 5.0V

100

10k

100k

10M

FREQUENCY (Hz)

Figure 45. CMRR Curve

OUTPUT CHARACTERISTICS

As already mentioned the output is rail-to-rail. When loading the output with a 10 kΩ resistor the maximum swing

of the output is typically 3 mV from the positive and negative rail.

The output of the LMV861 and LMV862 can drive currents up to 70 mA at 3.3V, and even up to 150 mA at 5V.

The LMV861 and LMV862 can be connected as non-inverting unity gain amplifiers. This configuration is the most

sensitive to capacitive loading. The combination of a capacitive load placed at the output of an amplifier along

with the amplifier’s output impedance creates a phase lag, which reduces the phase margin of the amplifier. If

the phase margin is significantly reduced, the response will be under damped which causes peaking in the

transfer and, when there is too much peaking, the op amp might start oscillating. The LMV861 and LMV862 can

directly drive capacitive loads up to 200 pF without any stability issues. In order to drive heavier capacitive loads,

an isolation resistor, R_ISO, should be used, as shown in Figure 46. By using this isolation resistor, the capacitive

load is isolated from the amplifier’s output, and hence, the pole caused by C_Lis no longer in the feedback loop.

The larger the value of R_ISO, the more stable the amplifier will be. If the value of R_ISOis sufficiently large, the

feedback loop will be stable, independent of the value of C_L. However, larger values of R_ISOresult in reduced

output swing and reduced output current drive.

ISO

OUT

Figure 46. Isolating Capacitive Load

A resistor value of around 50Ω would be sufficient. As an example some values are given in the following table,

for 5V and an open loop gain of 111 dB.

C_LOAD

300 pF

400 pF

500 pF

R_ISO

62Ω

55Ω

50Ω

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When increasing the closed-loop gain the capacitive load can be increased even further. With a closed loop gain

of 2 and a 27Ω isolation resistor, the load can be 1 nF

EMIRR

With the increase of RF transmitting devices in the world, the electromagnetic interference (EMI) between those

devices and other equipment becomes a bigger challenge. The LMV861 and LMV862 are EMI hardened op

amps which are specifically designed to overcome electromagnetic interference. Along with EMI hardened op

amps, the EMIRR parameter is introduced to unambiguously specify the EMI performance of an op amp. This

section presents an overview of EMIRR. A detailed description on this specification for EMI hardened op amps

can be found in Application Note AN-1698.

The dimensions of an op amp IC are relatively small compared to the wavelength of the disturbing RF signals. As

a result the op amp itself will hardly receive any disturbances. The RF signals interfering with the op amp are

dominantly received by the PCB and wiring connected to the op amp. As a result the RF signals on the pins of

the op amp can be represented by voltages and currents. This representation significantly simplifies the

unambiguous measurement and specification of the EMI performance of an op amp.

RF signals interfere with op amps via the non-linearity of the op amp circuitry. This non-linearity results in the

detection of the so called out-of-band signals. The obtained effect is that the amplitude modulation of the out-of-

band signal is downconverted into the base band. This base band can easily overlap with the band of the op

amp circuit. As an example Figure 47 depicts a typical output signal of a unity-gain connected op amp in the

presence of an interfering RF signal. Clearly the output voltage varies in the rhythm of the on-off keying of the RF

carrier.

NO RF

RF SIGNAL

+ V

DETECTED

OUT OPAMP

(A = 1)

Figure 47. Offset voltage variation due to an interfering RF signal

EMIRR Definition

To identify EMI hardened op amps, a parameter is needed that quantitatively describes the EMI performance of

op amps. A quantitative measure enables the comparison and the ranking of op amps on their EMI robustness.

Therefore the EMI Rejection Ratio (EMIRR) is introduced. This parameter describes the resulting input-referred

offset voltage shift of an op amp as a result of an applied RF carrier (interference) with a certain frequency and

level. The definition of EMIRR is given by:

≈

∆

’

◊

V_{RF_PEAK}

EMIRR_V

_{RF_PEAK}= 20 log

DV_OS

where

•

V_{RF_PEAK}is the amplitude of the applied un-modulated RF signal (V)

ΔV_OSis the resulting input-referred offset voltage shift (V)

(1)

The offset voltage depends quadratically on the applied RF level, and therefore, the RF level at which the EMIRR

is determined should be specified. The standard level for the RF signal is 100 mV_P. Application Note AN-1698

addresses the conversion of an EMIRR measured for an other signal level than 100 mV_P. The interpretation of

the EMIRR parameter is straightforward. When two op amps have EMIRRs which differ by 20 dB, the resulting

error signals when used in identical configurations, differs by 20 dB as well. So, the higher the EMIRR, the more

robust the op amp.

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Coupling an RF Signal to the IN+ Pin

Each of the op amp pins can be tested separately on EMIRR. In this section the measurements on the IN+ pin

(which, based on symmetry considerations, also apply to the IN- pin) are discussed. In Application Note AN-1698

the other pins of the op amp are treated as well. For testing the IN+ pin the op amp is connected in the unity gain

configuration. Applying the RF signal is straightforward as it can be connected directly to the IN+ pin. As a result

the RF signal path has a minimum of components that might affect the RF signal level at the pin. The circuit

diagram is shown in Figure 48. The PCB trace from RF_INto the IN+ pin should be a 50Ω stripline in order to

match the RF impedance of the cabling and the RF generator. On the PCB a 50Ω termination is used. This 50Ω

resistor is also used to set the bias level of the IN+ pin to ground level. For determining the EMIRR, two

measurements are needed: one is measuring the DC output level when the RF signal is off; and the other is

measuring the DC output level when the RF signal is switched on. The difference of the two DC levels is the

output voltage shift as a result of the RF signal. As the op amp is in the unity gain configuration, the input

referred offset voltage shift corresponds one-to-one to the measured output voltage shift.

10 µF

100 pF

RFin

Out

50W

100 pF

22 pF

10 µF

Figure 48. Circuit for coupling the RF signal to IN+

Cell Phone Call

The effect of electromagnetic interference is demonstrated in a setup where a cell phone interferes with a

pressure sensor application. The application is show in Figure 50.

This application needs two op amps and therefore a dual op amp is used. The op amp configured as a buffer

and connected at the negative output of the pressure sensor prevents the loading of the bridge by resistor R2.

The buffer also prevents the resistors of the sensor from affecting the gain of the following gain stage. The op

amps are placed in a single supply configuration.

The experiment is performed on two different op amps: a typical standard op amp and the LMV862, EMI

hardened dual op amp. A cell phone is placed on a fixed position a couple of centimeters from the op amps in

the sensor circuit.

When the cell phone is called, the PCB and wiring connected to the op amps receive the RF signal.

Subsequently, the op amps detect the RF voltages and currents that end up at their pins. The resulting effect on

the output of the second op amp is shown in Figure 49.

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Typical Opamp

LMV862

TIME (0.5s/DIV)

Figure 49. Comparing EMI Robustness

The difference between the two types of op amps is clearly visible. The typical standard dual op amp has an

output shift (disturbed signal) larger than 1V as a result of the RF signal transmitted by the cell phone. The

LMV862, EMI hardened op amp does not show any significant disturbances. This means that the RF signal will

not disturb the signal entering the ADC when using the LMV862.

2.4 kW

100W

PRESSURE

SENSOR

LMV862

ADC

LMV862

OUT

Figure 50. Pressure Sensor Application

DECOUPLING AND LAYOUT

Care must be given when creating a board layout for the op amp. For decoupling the supply lines it is suggested

that 10 nF capacitors be placed as close as possible to the op amp. For single supply, place a capacitor between

V⁺and V⁻. For dual supplies, place one capacitor between V⁺and the board ground, and a second capacitor

between ground and V⁻.

Even with the LMV861 and LMV862 inherent hardening against EMI, it is still recommended to keep the input

traces short and as far as possible from RF sources. Then the RF signals entering the chip are as low as

possible, and the remaining EMI can be, almost, completely eliminated in the chip by the EMI reducing features

of the LMV861 and LMV862.

LOAD CELL SENSOR APPLICATION

The LMV861 and LMV862 can be used for weight measuring system applications which use a load cell sensor.

Examples of such systems are: bathroom weight scales, industrial weight scales and weight measurement

devices on moving equipment such as forklift trucks.

The following example describes a typical load cell sensor application that can be used as a starting point for

many different types of sensors and applications. Applications in environments where EMI may appear would

especially benefit from the EMIRR performance of the LMV861 and LMV862.

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Load Cell Characteristics

The load cell used in this example is a Wheatstone bridge. The value of the resistors in the bridge changes when

pressure is applied to the sensor. This change of the resistor values will result in a differential output voltage

depending on the sensitivity of the sensor, the used supply voltage and the applied pressure. The difference

between the output at full scale pressure and the output at zero pressure is defined as the span of the load cell.

A typical value for the span is 10 mV/V.

The circuit configuration should be chosen such that loading of the sensor is prevented. Loading of the resistor

bridge due to the circuit following the sensor, could result in incorrect output voltages of the sensor.

Load Cell Example

Figure 51 shows a typical schematic for a load cell application. It uses a single supply and has an adjustment for

both positive and negative offset of the load cell. An ADC converts the amplified signal to a digital signal.

The op amps A1 and A2 are configured as buffers, and are connected at both the positive and the negative

output of the load cell. This is to prevent the loading of the resistor bridge in the sensor by the resistors

configuring the differential op amp circuit (op amp A4). The buffers also prevent the resistors of the sensor from

affecting the gain of the following gain stage. The third buffer (A3) is used to create a reference voltage, to

correct for the offset in the system.

Given the differential output voltage V_Sof the load cell, the output signal of this op amp configuration, V_OUT

equals:

« R5

≈

x V_{SENSE +}

x V_DD

x V_REF

V_OUT

(2)

To align the pressure range with the full range of an ADC the correct gain needs to be set. To calculate the

correct gain, the power supply voltage and the span of the load cell are needed. For this example a power supply

of 5V is used and the span of the sensor, in this case a 125 kg sensor, is 100 mV. With the configuration as

shown in Figure 51, this signal is covering almost the full input range of the ADC. With no weight on the load cell,

the output of the sensor and the op amp A4 will be close to 0V. With the full weight on the load cell, the output of

the sensor is 100 mV, and will be amplified with the gain from the configuration. In the case of the configuration

of Figure 51 the gain is R3/R1 = 51 kΩ/100Ω = 50. This will result in a maximum output of 100 mV x 50 = 5V,

which covers the full range of the ADC.

For further processing the digital signal can be processed by a microprocessor following the ADC, this can be

used to display or log the weight on the load cell. To get a resolution of 0.5 kg, the LSB of the ADC should be

smaller then 0.5 kg/125 kg = 1/1000. A 12-bit ADC would be sufficient as this gives 4096 steps. A 12-bit ADC

such as the two channel 12-bit ADC122S021 can be used for this application.

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5 kW

LOAD

CELL

100W

LMV861

ADC

LMV861

OUT

SENSE

100W

LMV861

5 kW

80 kW

REF

LMV861

20 kW

80 kW

Figure 51. Load Cell Application

IR PHOTODIODE APPLICATION

The LMV861 and LMV862 are also very good choices to be used in photodiode applications, such as IR

communication, monitoring, etc. The large bandwidth of the LMV861 and LM862 makes it possible to create high

speed detection. This, together with the low noise, makes the LMV861 and LMV862 ideal for medical

applications such as fetal monitors and bed side monitors. Another application where the LMV861 and LMV862

would fit perfectly is a bill validator, an instrument to detect counterfeit bank notes. The following example

describes an application that can be used for different types of photodiode sensors and applications.

IR Photodiode Example

The circuit shown in Figure 53 is a typical configuration for the readout of a photodiode. The response of a

photodiode to incoming light is a variation in the diode current. In many applications a voltage is required, i.e.

when connecting to an ADC. Therefore the first step is to convert the diode signal current into a voltage by an I-V

converter. In Figure 53 the left op amp is configured as an I-V converter, with a gain set by R1.

Some types of photodiodes can have a large capacitance. This could potentially lead to oscillation. The addition

of resistor R2 isolates the photodiode capacitance from the feedback loop, thereby preventing the loop from

oscillating.

The capacitor in between the two op amp configurations, blocks the DC component, thus removing the DC offset

of the first op amp circuit, and the offset created by the ambient light entering the photodiode. The second op

amp amplifies the signal to levels that can be converted to a digital signal by an ADC. To prevent floating of the

input of the second op amp, resistor R5 is added. By allowing the input bias current of a few pA to flow through

this resistor a stable input is ensured.

In Figure 52 a sensed and amplified signal is shown from an IR source, in this case an IR remote control.

The data from the ADC can then be used by a DSP or microprocessor for further processing.

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20 µs/DIV

Figure 52. IR Photodiode Signal

100 kW

1 MW

330W

1 nF

LMV861

OUT

ADC

LMV861

Photodiode

100W

100 kW

Figure 53. IR Photodiode Application

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REVISION HISTORY

Changes from Revision B (March 2013) to Revision C

Page

•

Changed layout of National Data Sheet to TI format .......................................................................................................... 19

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PACKAGE OPTION ADDENDUM

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10-Dec-2020

PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead finish/

Ball material

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

(1)

(2)

(3)

(4/5)

(6)

LMV861MG/NOPB

LMV861MGE/NOPB

LMV861MGX/NOPB

LMV862MM/NOPB

LMV862MMX/NOPB

ACTIVE

SC70

DCK

DGK

1000 RoHS & Green

250 RoHS & Green

Level-1-260C-UNLIM

-40 to 125

AEA

AJ5A

SC70

3000 RoHS & Green

1000 RoHS & Green

3500 RoHS & Green

VSSOP

⁽¹⁾The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

⁽²⁾RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance

do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may

reference these types of products as "Pb-Free".

RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.

Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based

flame retardants must also meet the <=1000ppm threshold requirement.

⁽³⁾MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

⁽⁴⁾There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

⁽⁵⁾Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

(6)

Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two

lines if the finish value exceeds the maximum column width.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

www.ti.com

10-Dec-2020

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 2

PACKAGE MATERIALS INFORMATION

www.ti.com

29-Oct-2021

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

LMV861MG/NOPB

LMV861MGE/NOPB

LMV861MGX/NOPB

LMV862MM/NOPB

LMV862MMX/NOPB

SC70

DCK

DGK

1000

250

178.0

330.0

8.4

2.25

5.3

2.45

3.4

1.2

1.4

4.0

8.0

SC70

3000

1000

3500

8.4

8.0

VSSOP

12.4

12.0

5.3

3.4

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

29-Oct-2021

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

LMV861MG/NOPB

LMV861MGE/NOPB

LMV861MGX/NOPB

LMV862MM/NOPB

LMV862MMX/NOPB

SC70

DCK

DGK

1000

250

208.0

367.0

191.0

367.0

35.0

SC70

3000

1000

3500

VSSOP

Pack Materials-Page 2

PACKAGE OUTLINE

DCK0005A

SOT - 1.1 max height

SMALL OUTLINE TRANSISTOR

2.4

1.8

0.1 C

1.4

1.1

1.1 MAX

PIN 1

INDEX AREA

NOTE 4

(0.15)

(0.1)

2X 0.65

1.3

2.15

1.85

1.3

0.33

0.23

0.1

0.0

(0.9)

TYP

0.1

C A B

0.15

0.22

0.08

GAGE PLANE

TYP

0.46

0.26

TYP

SEATING PLANE

4214834/C 03/2023

NOTES:

1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing

per ASME Y14.5M.

2. This drawing is subject to change without notice.

3. Refernce JEDEC MO-203.

4. Support pin may differ or may not be present.

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EXAMPLE BOARD LAYOUT

DCK0005A

SOT - 1.1 max height

SMALL OUTLINE TRANSISTOR

PKG

5X (0.95)

5X (0.4)

SYMM

(1.3)

2X (0.65)

(R0.05) TYP

(2.2)

LAND PATTERN EXAMPLE

EXPOSED METAL SHOWN

SCALE:18X

SOLDER MASK

OPENING

SOLDER MASK

OPENING

METAL UNDER

SOLDER MASK

METAL

EXPOSED METAL

0.07 MIN

ARROUND

0.07 MAX

ARROUND

NON SOLDER MASK

DEFINED

SOLDER MASK

DEFINED

(PREFERRED)

SOLDER MASK DETAILS

4214834/C 03/2023

NOTES: (continued)

4. Publication IPC-7351 may have alternate designs.

5. Solder mask tolerances between and around signal pads can vary based on board fabrication site.

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EXAMPLE STENCIL DESIGN

DCK0005A

SOT - 1.1 max height

SMALL OUTLINE TRANSISTOR

PKG

5X (0.95)

5X (0.4)

SYMM

(1.3)

2X(0.65)

(R0.05) TYP

(2.2)

SOLDER PASTE EXAMPLE

BASED ON 0.125 THICK STENCIL

SCALE:18X

4214834/C 03/2023

NOTES: (continued)

6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate

design recommendations.

7. Board assembly site may have different recommendations for stencil design.

www.ti.com

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