CATEGORIES

Current sensing

Current sense amplifiers

A current sense amplifier is a differential amplifier providing an analog output voltage proportional to the current flowing into a load connected on its input.

current sense amplifier

ST's current sense amplifier IC portfolio offers a large variety of high-performance devices.

current sense amplifier

Current sensing solutions add valuable safety and protection features to system designs. They provide information to control current in power systems and avoid overheating and short circuits. Current sensing is also an essential part of energy metering to ensure power-efficiency and minimize environmental impact.

Key features

The main features of ST's portfolio of current sensing ICs ensure robustness and application safety:

  • -20 to +70 V line monitoring
  • Bidirectional or unidirectional current measurement
  • Integrated solutions for faster design time and reduced bill of materials
    • Integrated EMI filters
    • Pin selectable gain
    • Shutdown function
  • Robust devices that do not require external protection
  • Automotive-grade qualified

 

10 years longevity commitment

High-voltage

Tolerance to high voltage ranges and protection mechanisms to handle negative voltage are essential in high-power systems such as batteries in electric vehicles. Our current sense amplifiers can work in high voltage applications avoiding additional external protections components and simplifying the final schematic.

Precision / high-accuracy

Using a precision current sense amplifier allows designers to measure small voltage drops across shunt resistors with minimal error. Small shunt resistors values are necessary to minimize the power dissipation. Thanks to highly accurate current measurements, precision current sense amplifiers offer a better efficiency and thermal performance.

View all current sensing ICs


What are the main benefits of a current sense amplifier?

Current sense amplifiers provide several benefits for designers, including the possibility to:

  • measure current ranging from a few milli amperes to several hundreds
  • perform real-time current measurement in several topologies
  • precisely measure current, thanks to an integrated matched resistive gain network
  • reduce PCB size thanks to integrated gain resistance
  • sustain extended input common mode voltage, far beyond the power supply rail

How does a current sense amplifier work?

current sense amplifier circuit
Circuit example

The working principle of a current sensing amplifier is based on Ohm's law. When load current flows through a shunt resistor (Rshunt) present on inputs, it generates a voltage drop called VSENSE. This voltage is generally small to limit power dissipation losses.

VSENSE is then amplified with an internal instrumentation amplifier. The resulting output voltage (VOUT) is a voltage which is proportional to the Ioad current. It can then be processed with an ADC (analog-to-digital converter).

What are the main types of current sense amplifiers?

high side low side current sense amplifier circuit
Circuit example

High-side amplifiers

The current is measured between the supply rail and the load. The DC voltage applied on the input pins can be much higher than the power supply.

Benefits
  • Short-to-ground fault detection
  • High immunity against ground disturbance
  • Current monitored directly from the source
Challenges
  • High-input common-mode voltages
  • Support fast variation of input common mode voltage

Low-side amplifiers

The current is measured between the load and the ground. The voltage applied on the input pins is close to the ground.

Benefits
  • Simple implementation
  • Cost-effective solution
  • VICM (input common-mode voltage) close to GND (zero-voltage point)
Challenges
  • Difficult to detect short-cut to ground
  • Multiple output power supply (all current are combined in GND line)
  • May disturb the ground voltage seen by the load

Bi-directional VS unidirectional

In some applications, the current can flow into the load in both directions. This is the case for motor control applications used in H-Bridge topologies. In this case, the current sense amplifier must have one additional pin, called VREF. The VREF pin allows designers to set the output reference anywhere within the power supply range. A bidirectional amplifiers can be used as a unidirectional current sense amplifier, setting the reference to one voltage rail.

How to choose the right current sense amplifier for your design?

  1. Define the configuration required for your device

    High-side configuration: Select the current sense amplifier depending of the max common mode voltage (VICM) required by the application and its power supply (VCC).

    Low-side configuration: Select a current sense amplifier that can work with a common mode voltage close to 0 volts.
    Operational amplifiers can be also used, adding 4 external resistors to set the gain. However, the size of the PCB will be larger and accuracy can be lower.

  2. Look into the direction of current flows

    After defining the configuration required, ask yourself if the current in your application needs to flow in both directions, in order to choose a bidirectional or unidirectional current sensing.

  3. If accurate measurements are needed

    Several parameters related to the application must be taken into account. Depending on the current range to be measured and the shunt resistor used, the voltage drop into the shunt resistor can be very small (hundreds of µV). For better accuracy, it is important to consider the error related to offset and accuracy gain.

Discover and test high-performance
op amps by using this Sample Kit
Smart power sensing - Skateboard demo with the TSC1641 digital power monitor
Current Sensing
Quick Reference Guide

Low/high-side bidirectional current sense amplifiers for industrial and automotive applications

Based on a zero-drift architecture that delivers high performance for precision current sensing, the TSC21x family brings excellent accuracy and robustness to your design.

TSC21x products are available in six different versions (TSC210 / TSC211 / TSC212 / TSC213 / TSC214 / TSC215), offering different gain. They can operate over a broad supply voltage range, from 2.7 to 26 V, and support temperatures ranging from -40 to 125 °C, making them ideal for industrial and automotive applications.

Evaluation board is also available, to support developers in their designs

STEVAL-AETKT2V1

Low- and high-side current sense amplifiers with overcurrent protection for automotive, industrial, and telecom applications

The TSC200, TSC201, and TSC202 are current sense amplifiers delivering an analog voltage output, designed for both high- and low-side sensing.

The devices can detect current through a shunt resistor across -20 V to +80 V of common-mode voltage, featuring an amplification gain of 20 V/V for TSC200, 50 V/V for TSC201, and 100 V/V for TSC202.

AEC-Q100 qualified, the TSC200, TSC201, and TSC202 integrate an open-drain comparator with an output latch function and an internal 0.6 V voltage reference connected to the input.

To support developers in their designs is available the STEVAL-AETKT3V1 evaluation kit.

The ultimate solution for high voltage (100 V) precision current sensing in Automotive and Industrial applications

AEC-Q100 automotive qualified and packaged in both standard SO-8 and MiniSO-8, the TSC2020, TSC2021, and TSC2022 are designed to sense very low drop voltages, resulting so the perfect choice for precision current measurement, overcurrent protection, current monitoring, and feedback loops.

With advanced bidirectional sensing capabilities and available in three fixed gain version, x20 V/V (TSC2020), x50 V/V (TSC2021), x100 V/V (TSC2022), the devices can accurately sense currents up to 100 V common mode voltage via a shunt resistor.

The STEVAL-AETK41V1 evaluation kit is available to support engineers in their design.

High-voltage, bidirectional current-sense amplifiers

Able to sense very low drop voltages as low as 10 mV, our TSC2010 (20 V/V Gain), TSC2011 (60 V/V) and TSC2012 (100 V/V) high-voltage bidirectional current sense amplifiers (available both as Automotive and Industrial grade) can sense the current thanks to a shunt resistor over a wide range of common mode voltages from –20 to + 70 V, regardless of the supply voltage. Available also with extended temperature range (-40 to 150 °C) : TSC2010H, TSC2011H and TSC2012H.

An Evaluation board can be ordered (STEVAL-AETKT1V2), to support developers in their designs.

eDesignSuite

eDesignSuite is a comprehensive set of easy-to-use design-aid utilities ready to help you streamline the system development process with a wide range of ST products.

Power Management Design Center

Thermal-electrical Simulators for Components

Signal Conditioning Design Tool

NFC/RFID Calculators

Choose design tool:
Power Management Design Center

Power Supply Design Tool

SMPS design, by topology, by type and by product
PFC design with analog and digitial control
Supports various PCB configurations
Choose type:
DC/DC
AC/DC
Solar Battery Charger
Power Management Design Center

LED Lighting Design Tool

Handles AC-DC and DC-DC design in common topologies
Displays interactive and annotated schematic
Provides current/voltage graphs, Bode plots, efficiency curves and power-loss data
Choose type:
DC/DC
AC/DC
Power Management Design Center

Digital Power Workbench

Provides a step-by-step optimized design of power section and control loop
Generates the STM32Cube embedded software package for custom applications and allows firmware project generation, compatible with multiple STM32 IDEs
Power Management Design Center

Power Tree Designer

Specify input/output power for each node in the tree
Check for consistency
Design each individual node
Choose design tool:
Thermal-electrical Simulators for Components

AC Switches Simulator

Select ratings and application waveforms
Get junction temperature and blocking voltage graphs
Search and sort suitable devices
Thermal-electrical Simulators for Components

Rectifier Diodes Simulator

Select ratings and application waveforms
Estimate power losses
Search and sort suitable devices
Thermal-electrical Simulators for Components

STPOWER Studio

Supports long mission profiles
Provides power loss and temperature graphs
Helps define heatsink thermal properties
Thermal-electrical Simulators for Components

Twister Sim

Help select the right ViPOWER Automotive power device
Supports load-compatibility, wiring harness optimization, fault condition impact and diagnostic analysis
Supports various PCB configurations
Thermal-electrical Simulators for Components

TVS Simulator

Specify system ratings and surge waveform
Search and sort suitable devices
Thermal-electrical Simulators for Components

Estimate

Build simple schematics and firmware inputs in minutes
Quickly generate reliable estimates of battery life, system power consumption and bill of materials costs
Choose design tool:
Signal Conditioning Design Tool

Active Filters

Handles multi-stage-designs and common topologies
Returns circuit component values
Provides gain, phase and group delay graphs
Low Pass, High Pass and Band Pass
Signal Conditioning Design Tool

Comparators

Handles most common configurations
Returns circuit components values
Provides I/O signal waveforms
Inverting, Non Inverting, Window
Signal Conditioning Design Tool

Low side Current Sensing

Returns circuit component values
Provides current error graphs
Signal Conditioning Design Tool

High side Current Sensing

Provides current error graphs.
Help to select the right High side current sensing and shunt devices.
Choose design tool:
NFC/RFID Calculators

NFC Inductance

Input geometry and substrate properties
Get antenna impedance
NFC/RFID Calculators

UHF Link Budget

Enter forward and reverse link characteristics
The tool returns link budget estimate
NFC/RFID Calculators

NFC Tuning Circuit

Enter antenna parameter and matching target
Select the topology of the matching network
The tool returns component values for the desired design targets