Home Power management Voltage references Shunt voltage references

LM4040-N-Q1

ACTIVE

Automotive, 100-ppm/°C precision micropower shunt voltage reference

Product details

VO (V) 2.5, 3 Initial accuracy (max) (%) 0.1, 0.2, 0.5, 1, 2 VO adj (min) (V) 2.048 VO adj (max) (V) 3 Iz for regulation (min) (µA) 45 Reference voltage (V) Fixed Rating Automotive TI functional safety category Functional Safety-Capable Temp coeff (max) (ppm/°C) 100, 150 Operating temperature range (°C) -40 to 125 Iout/Iz (max) (mA) 15
VO (V) 2.5, 3 Initial accuracy (max) (%) 0.1, 0.2, 0.5, 1, 2 VO adj (min) (V) 2.048 VO adj (max) (V) 3 Iz for regulation (min) (µA) 45 Reference voltage (V) Fixed Rating Automotive TI functional safety category Functional Safety-Capable Temp coeff (max) (ppm/°C) 100, 150 Operating temperature range (°C) -40 to 125 Iout/Iz (max) (mA) 15
SOT-23 (DBZ) 3 6.9204 mm² 2.92 x 2.37
  • LM4040-N-Q1 AEC Q-100 qualified for automotive applications
    • Extended Grade 1: −40°C to +125°C, TA
    • Industrial Grade 3: −40°C to +85°C, TA
  • Small packages: SOT-23, TO-92, and SC70
  • No output capacitor required
  • Tolerates capacitive loads
  • Fixed reverse breakdown voltages of 2.048V, 2.5V, 3V, 4.096V, 5V, 8.192V, and 10V
  • Key specifications (2.5V LM4040-N)
    • Output voltage tolerance (A Grade, 25°C): ±0.1% (maximum)
    • Low output noise (10Hz to 10kHz): 35µVrms (typical)
    • Wide operating current range: 60µA to 15mA
    • Industrial temperature range: −40°C to +85°C
    • Extended temperature range: −40°C to +125°C
    • Low temperature coefficient: 100ppm/°C (maximum)
  • LM4040-N-Q1 AEC Q-100 qualified for automotive applications
    • Extended Grade 1: −40°C to +125°C, TA
    • Industrial Grade 3: −40°C to +85°C, TA
  • Small packages: SOT-23, TO-92, and SC70
  • No output capacitor required
  • Tolerates capacitive loads
  • Fixed reverse breakdown voltages of 2.048V, 2.5V, 3V, 4.096V, 5V, 8.192V, and 10V
  • Key specifications (2.5V LM4040-N)
    • Output voltage tolerance (A Grade, 25°C): ±0.1% (maximum)
    • Low output noise (10Hz to 10kHz): 35µVrms (typical)
    • Wide operating current range: 60µA to 15mA
    • Industrial temperature range: −40°C to +85°C
    • Extended temperature range: −40°C to +125°C
    • Low temperature coefficient: 100ppm/°C (maximum)

Designed for space-critical applications, the LM4040-N precision voltage reference is available in small SC70 and SOT-23 surface-mount package. The advanced design of the LM4040-N eliminates the need for an external stabilizing capacitor while maintaining stability with any capacitive load, thus making the LM4040-N easy to use. Further reducing design effort is the availability of several fixed reverse breakdown voltages: 2.048V, 2.5V, 3V, 4.096V, 5V, 8.192V, and 10V. The minimum operating current increases from 60µA for the 2.5V LM4040-N to 100µA for the 10V LM4040-N. All versions have a maximum operating current of 15mA.

The LM4040-N uses a fuse and Zener-zap reverse breakdown voltage trim during wafer sort to make sure that the prime parts have an accuracy of better than ±0.1% (A grade) at 25°C. Bandgap reference temperature drift curvature correction and low dynamic impedance provide stable reverse breakdown voltage accuracy over a wide range of operating temperatures and currents.

Also available is the LM4041-N with two reverse breakdown voltage versions: adjustable and 1.2V. See the LM4041-N data sheet (SNOS641).

Designed for space-critical applications, the LM4040-N precision voltage reference is available in small SC70 and SOT-23 surface-mount package. The advanced design of the LM4040-N eliminates the need for an external stabilizing capacitor while maintaining stability with any capacitive load, thus making the LM4040-N easy to use. Further reducing design effort is the availability of several fixed reverse breakdown voltages: 2.048V, 2.5V, 3V, 4.096V, 5V, 8.192V, and 10V. The minimum operating current increases from 60µA for the 2.5V LM4040-N to 100µA for the 10V LM4040-N. All versions have a maximum operating current of 15mA.

The LM4040-N uses a fuse and Zener-zap reverse breakdown voltage trim during wafer sort to make sure that the prime parts have an accuracy of better than ±0.1% (A grade) at 25°C. Bandgap reference temperature drift curvature correction and low dynamic impedance provide stable reverse breakdown voltage accuracy over a wide range of operating temperatures and currents.

Also available is the LM4041-N with two reverse breakdown voltage versions: adjustable and 1.2V. See the LM4041-N data sheet (SNOS641).

Download View video with transcript Video

Similar products you might be interested in

open-in-new Compare alternates
Drop-in replacement with upgraded functionality to the compared device
LM4050-N-Q1 ACTIVE Automotive, 50-ppm/°C precision micropower shunt voltage reference LM4050-N-Q1 offers fixed voltage option at higher initial accuracy and much lower 50 ppm/°C temperature drift.

Technical documentation

star =Top documentation for this product selected by TI
No results found. Please clear your search and try again.
View all 8
Type Title Date
* Data sheet LM4040-N/-Q1 Precision Micropower Shunt Voltage Reference datasheet (Rev. L) 29 Jun 2024
Application brief Discrete Power Design for C2000™ PDF | HTML 15 Aug 2024
Application brief Using Voltage Supervisors in High Voltage Applications (Rev. B) PDF | HTML 20 Feb 2023
Functional safety information LM4040-N-Q1 Functional Safety FIT Rate, FMD and Pin FMA (Rev. A) PDF | HTML 18 Dec 2019
E-book Voltage Supervisor and Reset ICs: Tips, Tricks and Basics 28 Jun 2019
Technical article How to use a voltage reference as a voltage regulator PDF | HTML 04 Dec 2018
Application note AN-1525 Single Supply Operation of the DAC0800 and DAC0802 (Rev. A) 22 Apr 2013
Application note Negative Buck Switching Regulator (using LM258x) 21 Mar 2007

Design & development

For additional terms or required resources, click any title below to view the detail page where available.

Simulation model

LM4040_NA10P0 PSpice Transient Model

SNOM420.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA10P0 TINA-TI Transient Reference Design

SNOM449.TSC (71 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA10P0 TINA-TI Transient Spice Model

SNOM448.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA10P0 Unencrypted PSpice Transient Model

SNOM495.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NA2P048 PSpice Transient Model

SNOM394.ZIP (36 KB) - PSpice Model
Simulation model

LM4040_NA2P048 TINA-TI Transient Reference Design

SNOM444.TSC (72 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA2P048 TINA-TI Transient Spice Model

SNOM445.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA2P5 PSpice Transient Model

SNOM403.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA2P5 TINA-TI Transient Spice Model

SNOM455.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA2P5 Transient TINA-TI Reference Design

SNOM454.TSC (72 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA2P5 Unencrypted PSpice Transient Model

SNOM526.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NA3P0 PSpice Transient Model

SNOM423.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA3P0 TINA-TI Transient Reference Design

SNOM457.TSC (72 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA3P0 TINA-TI Transient Spice Model

SNOM456.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA3P0 Unencrypted PSpice Transient Model

SNOM547.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NA4P096 PSpice Transient Model

SNOM410.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA4P096 TINA-TI Transient Reference Design

SNOM453.TSC (72 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA4P096 TINA-TI Transient Spice Model

SNOM452.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA4P096 Unencrypted PSpice Transient Model

SNOM505.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NA5P0 PSpice Transient Model

SNOM405.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA5P0 TINA-TI Transient Reference Design

SNOM450.TSC (72 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA5P0 TINA-TI Transient Spice Model

SNOM451.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA5P0 Unencrypted PSpice Transient Model

SNOM500.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NA8P192 PSpice Transient Model

SNOM421.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NA8P192 TINA-TI Transient Reference Design

SNOM447.TSC (73 KB) - TINA-TI Reference Design
Simulation model

LM4040_NA8P192 TINA-TI Transient Spice Model

SNOM446.ZIP (9 KB) - TINA-TI Spice Model
Simulation model

LM4040_NA8P192 Unencrypted PSpice Transient Model

SNOM496.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB10P0 PSpice Transient Model

SNOM407.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB10P0 Unencrypted PSpice Transient Model

SNOM502.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB2P048 PSpice Transient Model

SNOM393.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB2P048 Unencrypted PSpice Transient Model

SNOM546.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB2P5 PSpice Transient Model

SNOM395.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB2P5 Unencrypted PSpice Transient Model

SNOM545.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB3P0 PSpice Transient Model

SNOM401.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB3P0 Unencrypted PSpice Transient Model

SNOM525.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB4P096 PSpice Transient Model

SNOM418.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB4P096 Unencrypted PSpice Transient Model

SNOM494.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB5P0 PSpice Transient Model

SNOM413.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB5P0 Unencrypted PSpice Transient Model

SNOM508.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NB8P192 PSpice Transient Model

SNOM408.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NB8P192 Unencrypted PSpice Transient Model

SNOM503.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC10P0 PSpice Transient Model

SNOM422.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC10P0 Unencrypted PSpice Transient Model

SNOM497.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC2P48 PSpice Transient Model

SNOM417.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC2P5 PSpice Transient Model

SNOM400.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC2P5 Unencrypted PSpice Transient Model

SNOM541.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC3P0 PSpice Transient Model

SNOM416.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC3P0 Unencrypted PSpice Transient Model

SNOM548.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC4P096 PSpice Transient Model

SNOM411.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC4P096 Unencrypted PSpice Transient Model

SNOM506.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC5P0 PSpice Transient Model

SNOM406.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC5P0 Unencrypted PSpice Transient Model

SNOM501.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NC8P192 PSpice Transient Model

SNOM412.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NC8P192 Unencrypted PSpice Transient Model

SNOM507.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND10P0 PSpice Transient Model

SNOM409.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND10P0 Unencrypted PSpice Transient Model

SNOM504.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND2P48 PSpice Transient Model

SNOM414.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND2P5 PSpice Transient Model

SNOM398.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND2P5 Unencrypted PSpice Transient Model

SNOM542.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND3P0 PSpice Transient Model

SNOM404.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND3P0 Unencrypted PSpice Transient Model

SNOM539.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND4P096 PSpice Transient Model

SNOM415.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND4P096 Unencrypted PSpice Transient Model

SNOM493.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND5P0 PSpice Transient Model (Rev. A)

SNOM419A.ZIP (102 KB) - PSpice Model
Simulation model

LM4040_ND5P0 Unencrypted PSpice Transient Model (Rev. A)

SNOM499A.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_ND8P192 PSpice Transient Model

SNOM399.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_ND8P192 Unencrypted PSpice Transient Model

SNOM498.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NE2P048 PSpice Transient Model

SNOM397.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NE2P048 Unencrypted PSpice Transient Model

SNOM543.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NE2P5 PSpice Transient Model

SNOM396.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NE2P5 Unencrypted PSpice Transient Model

SNOM544.ZIP (1 KB) - PSpice Model
Simulation model

LM4040_NE3P0 PSpice Transient Model

SNOM402.ZIP (25 KB) - PSpice Model
Simulation model

LM4040_NE3P0 Unencrypted PSpice Transient Model

SNOM540.ZIP (1 KB) - PSpice Model
Calculation tool

SHUNT-REFERENCE-CALC Shunt Reference Selector and Design Calculator

This tool guides the user through the design process for the TLx431 and LM40x0 family of shunt voltage references. This calculator will recommend resistance and capacitance values to optimally meet the user's desired specifications.
Supported products & hardware

Supported products & hardware

Products
Shunt voltage references
ATL431 2.5-V low-IQ adjustable precision shunt regulator ATL431LI Low-IQ programmable shunt regulator offered in an ultra-small DQN package ATL431LI-Q1 Automotive, high-bandwidth, low-IQ programmable shunt regulator (pinout: KRA) ATL432 2.5-V precision programmable shunt regulator ATL432LI High-bandwidth, low-IQ programmable shunt regulator (pinout: RKA) ATL432LI-Q1 Automotive, high-bandwidth, low-IQ programmable shunt regulator (pinout: RKA) LM4030 Ultra-high-precision shunt voltage reference LM4040 Fixed voltage, 45-µA, precision micropower shunt voltage reference LM4040-N 100-ppm/°C precision micropower shunt voltage reference LM4040-N-Q1 Automotive, 100-ppm/°C precision micropower shunt voltage reference LM4040C25-EP Enhanced Product 2.5-V Precision Micropower Shunt Voltage Reference, 0.5% accuracy LM4041-N Fixed & adjustable, 45-µA, precision micropower shunt voltage reference LM4041-N-Q1 Automotive, precision micropower shunt voltage reference LM4041A12 1.2-V precision micropower shunt voltage reference with 0.1% accuracy LM4041B Adjustable, precision micropower shunt voltage reference with 0.2% accuracy LM4041B12 1.2-V precision micropower shunt voltage reference with 0.2% accuracy LM4041C Adjustable, precision micropower shunt voltage reference with 0.5% accuracy LM4041C12 1.2-V precision micropower shunt voltage reference with 0.5% accuracy LM4041D Adjustable, precision micropower shunt voltage reference with 1% accuracy LM4041D12 1.2-V precision micropower shunt voltage reference with 1% accuracy LM4050-N 50-ppm/°C precision micropower shunt voltage reference LM4050-N-Q1 Automotive, 50-ppm/°C precision micropower shunt voltage reference LM4050QML-SP Radiation-hardened QMLV, 2.5-V or 5-V shunt voltage reference LM4051-N Fixed & adjustable, precision micropower shunt voltage reference LMV431 1.5%, low-voltage (1.24-V) adjustable precision shunt regulator LMV431A 1%, low-voltage (1.24-V) adjustable precision shunt regulator LMV431B 0.5%, low-voltage (1.24-V) adjustable precision shunt regulator TL431 Adjustable precision shunt regulator TL431-Q1 Automotive adjustable precision shunt regulator (pin layout: KRA) TL431C 2% adjustable precision shunt regulator TL431LI Adjustable precision shunt regulator with optimized reference current (pin layout: KRA) TL431LI-Q1 Automotive, adjustable, precision shunt regulator with optimized reference current TL432 Adjustable precision shunt regulator (reverse pinout) TL432-Q1 Automotive adjustable precision shunt regulator (pin layout: RKA) TL432LI Adjustable precision shunt regulator with optimized reference current (pin layout: RKA) TL432LI-Q1 Automotive, adjustable, precision shunt regulator with optimized reference current TLA431 All-capacitor stable precision programmable reference with KRA pin layout TLA432 All-capacitor stable precision programmable reference with RKA pin layout TLV431 1.5% accuracy, low-voltage, adjustable precision shunt regulator TLV431A 1% accuracy, low-voltage, adjustable precision shunt regulator TLV431A-Q1 Automotive, low-voltage adjustable precision shunt regulator TLV431B 0.5% accuracy, low-voltage, adjustable precision shunt regulator TLV431B-Q1 Automotive, low-voltage adjustable precision shunt regulator TLVH431 1.5% low-voltage wide-operating current adjustable precision shunt regulator TLVH431A 1% low-voltage wide-operating current adjustable precision shunt regulator TLVH431A-Q1 Automotive, low-voltage adjustable precision shunt regulator TLVH431B 0.5% low-voltage wide-operating current adjustable precision shunt regulator TLVH431B-EP Enhanced-plastic 0.5% low-voltage wide-operating-current adjustable precision shunt regulator TLVH431B-Q1 Automotive, low-voltage adjustable precision shunt regulator (reverse pinout) TLVH432 1.5% low-voltage wide-operating current adjustable precision shunt regulator (reverse pinout) TLVH432A 1% low-voltage wide-operating current adjustable precision shunt regulator (reverse pinout) TLVH432B 0.5% low-voltage wide-operating current adjustable precision shunt regulator (reverse pinout)
General-purpose op amps
TLV4313 Quad, 5.5-V, 1-MHz, low quiescent current (65-μA), RRIO operational amplifier TLV4314 Quad, 5.5-V, 3-MHz, RRIO operational amplifier TLV4314-Q1 Automotive-grade, quad, 5.5-V, 3-MHz, RRIO operational amplifier TLV4316 Quad, 5.5-V, 10-MHz, RRIO operational amplifier TLV4316-Q1 Automotive-grade, quad, 5.5-V, 10-MHz, RRIO operational amplifier TLV4379 Quad, 5.5-V, 90-kHz, low quiescent current (4-μA), RRIO operational amplifier
Precision op amps (Vos<1mV)
TLV4333 Quad, 350-kHz, low-noise, RRIO, CMOS operational amplifier for cost-sensitive systems TLV4376 Quad 5.5-MHz, 100-µV offset, 8-nV/√Hz noise, 815-µA power, precision operational amplifiers TLV4387 Quad, ultra-high-precision (10 μV) zero-drift (0.01 μV/°C) low-input-bias-current op amp
Calculation tool

SHUNT_VOLTAGE_REFERENCE_RESISTOR_CALCULATOR Shunt Voltage Reference External Resistor Quick Start Calculator

This external resistor quick-start calculator tool lets you easily calculate valid external resistor values relative to voltage reference, supply and load-current bounds. With these inputs, you can instantly view the resulting calculations and use the color-coded indications to understand (...)

Supported products & hardware

Supported products & hardware

Products
Die & wafer services
LM336-2.5-MIL Shunt Voltage Reference
Shunt voltage references
ATL431 2.5-V low-IQ adjustable precision shunt regulator LM136-2.5-N Voltage Reference Diode LM136-5.0 5.0V Reference Diode LM136-5.0QML 5.0V Reference Diode LM136A-2.5QML 2.5V Reference Diode LM136A-2.5QML-SP Radiation-hardened QMLV, 2.5-V shunt voltage reference LM136A-5.0QML 5.0V Reference Diode LM185-1.2-N Micropower Voltage Reference Diode LM185-1.2QML Micropower Voltage Reference Diode LM185-1.2QML-SP Radiation-hardened QMLV, 1.2-V shunt voltage reference LM185-2.5-N Micropower Voltage Reference Diode LM185-2.5QML Micropower Voltage Reference Diode LM185-2.5QML-SP Space-grade QMLV 2.5-V  shunt voltage reference LM185-ADJ Adjustable Micropower Voltage Reference LM185QML Adjustable Micropower Voltage Reference LM285-1.2 1.235-V, –40°C to +85°C, micropower voltage reference LM285-1.2-N 1.235-V, –40°C to +85°C, micropower voltage reference diode LM285-2.5 2.5-V, –40°C to +85°C, micropower voltage reference LM285-2.5-N 2.5-V, –40°C to +85°C, micropower voltage reference diode LM285-ADJ Adjustable, 85°C, micropower voltage reference LM336-2.5 0°C to 70°C, 2.5-V integrated reference circuit LM336-2.5-N Voltage reference diode LM336-5.0 5-V reference diode LM385-1.2 1.235-V, 2%, 0°C to 70°C, micropower voltage reference LM385-1.2-MIL Micropower Voltage Reference LM385-1.2-N 1.235-V, 0°C to 70°C, micropower voltage reference diode LM385-2.5 2.5-V, 2%, 70°C, micropower voltage reference LM385-2.5-N 2.5-V, 0°C to 70°C, micropower voltage reference diode LM385-ADJ Adjustable, 70°C, micropower voltage reference LM4030 Ultra-high-precision shunt voltage reference LM4040 Fixed voltage, 45-µA, precision micropower shunt voltage reference LM4040-N 100-ppm/°C precision micropower shunt voltage reference LM4040-N-Q1 Automotive, 100-ppm/°C precision micropower shunt voltage reference LM4041-N Fixed & adjustable, 45-µA, precision micropower shunt voltage reference LM4041-N-Q1 Automotive, precision micropower shunt voltage reference LM4050-N 50-ppm/°C precision micropower shunt voltage reference LM4050-N-Q1 Automotive, 50-ppm/°C precision micropower shunt voltage reference LM4050QML-SP Radiation-hardened QMLV, 2.5-V or 5-V shunt voltage reference LM4051-N Fixed & adjustable, precision micropower shunt voltage reference LM431 2%, 1%, or 0.5% accuracy, adjustable precision Zener shunt regulator LM4431 Micropower shunt voltage reference LMV431 1.5%, low-voltage (1.24-V) adjustable precision shunt regulator LMV431A 1%, low-voltage (1.24-V) adjustable precision shunt regulator LMV431B 0.5%, low-voltage (1.24-V) adjustable precision shunt regulator
Current references
LM134 3-Terminal Adjustable Current Source LM234 100°C 3-pin adjustable current source LM334 0°C to 70°C 3-pin adjustable current source
Simulation tool

PSPICE-FOR-TI — PSpice® for TI design and simulation tool

PSpice® for TI is a design and simulation environment that helps evaluate functionality of analog circuits. This full-featured, design and simulation suite uses an analog analysis engine from Cadence®. Available at no cost, PSpice for TI includes one of the largest model libraries in the (...)
Reference designs

TIDA-00143 — Automotive 60W Brushless DC (BLDC) Motor Drive

This TIDA-00143 reference design is a BLDC motor controller and is designed to operate from a single 12V (nominal) power supply which can vary over a wide range of voltages as found in typical automotive applications.  The board is designed to drive motors in the 60W range, which require (...)
Design guide: PDF
Schematic: PDF
Reference designs

TIDA-01514 — Protection and Light-Load Detection Reference Design for Antenna Modules

The TIDA-01514 reference design provides protection and diagnostics for antenna modules for use in automotive infotainment and navigation systems. This design is an alternate solution for antenna low-dropout linear regulators (LDOs) for the purpose of achieving lower ohmic drop (IR) while meeting (...)
Design guide: PDF
Schematic: PDF
Package Pins CAD symbols, footprints & 3D models
SOT-23 (DBZ) 3 Ultra Librarian

Ordering & quality

Information included:
  • RoHS
  • REACH
  • Device marking
  • Lead finish/Ball material
  • MSL rating/Peak reflow
  • MTBF/FIT estimates
  • Material content
  • Qualification summary
  • Ongoing reliability monitoring
Information included:
  • Fab location
  • Assembly location

Support & training

TI E2E™ forums with technical support from TI engineers

Content is provided "as is" by TI and community contributors and does not constitute TI specifications. See terms of use.

If you have questions about quality, packaging or ordering TI products, see TI support. ​​​​​​​​​​​​​​

Videos