TVS Diodes

Littelfuse offers a broad range of TVS diodes, including high peak pulse current and peak pulse power options up to 10kA and 30kW respectively. Littelfuse backs our products with over 80 years of circuit protection expertise and application knowledge developed by working with our industry-leading customers. You can learn more about our range of tvs diode products by viewing our TVS diode selection guide.

The Transient Voltage Suppressor diode (also known as a TVS Diode) is a protection diode designed to protect electronic circuits against transients and overvoltage threats such as EFT (electrically fast transients) and ESD (electro-static discharge). TVS Diodes are silicon avalanche devices typically chosen for their fast response time (low clamping voltage), lower capacitance and low leakage current. Littelfuse TVS diodes are available in both uni-directional (uni-polar) or bi-directional (bi-polar) diode circuit configurations.

When selecting TVS Diodes there are some important parameters to be considered, these are; Reverse Standoff Voltage (VR), Peak Pulse Current (IPP) and Maximum Clamping Voltage (VC max). View the TVS diode selection guide to learn more about how to select these devices and Littelfuse’s complete TVS diode offering

What are TVS Diodes?

TVS Diodes are electronic components designed to protect sensitive electronics from high-voltage transients. They can respond to overvoltage events faster than most other types of circuit protection devices, and are offered in a variety of surface mount and through-hole circuit board mounting formats.

They function by limiting voltage to a certain level (referred to as a "clamping" device) with p-n junctions that have a larger cross-sectional area than those of a normal diode, allowing them to conduct large currents to ground without sustaining damage.

TVS Diodes are generally used to protect against electrical overstress such as those induced by lightning strikes, inductive load switching, and electro-static discharge (ESD) associated with transmission on data lines and electronic circuits.

Littelfuse TVS Diodes can fit a wide range of circuit protection applications but were primarily designed to protect I/O interfaces in telecommunication and industrial equipment, computers and consumer electronics.

Littelfuse TVS Diode characteristics include:

  • Low incremental surge resistance
  • Unidirectional and Bidirectional polarities available
  • Reverse standoff voltages range from 5 to 512V
  • RoHS compliant–Matte Tin Pb-free plated
  • Surface-mount power ratings from 400W to 5,000W
  • Axial lead power ratings from 400W to 30,000W (30kW)
  • High current protection available for 6kA and 10kA

For insight about other Transient Suppression Technologies and how they compare, please refer to Littelfuse Application Note AN9768.

Littelfuse TVS Diode Product Selection Table

TVS Diodes are used to protect semiconductor components from high-voltage transients. Their p-n junctions have a larger cross-sectional area than those of a normal diode, allowing them to conduct large currents to ground without sustaining damage. Littelfuse supplies TVS Diodes with peak power ratings from 400W to 30kW, and reverse standoff voltages from 5V to 495V.

You can get additional TVS Diode selection guidance by visiting the TVS Diode definition and selection page by clicking here

Series Name and Page Link Package Type Reverse Standoff Voltage (VR) Peak Pulse Power Range2 (PPP) Peak Pulse Current
(IPP 8x20μs)
Operating Temperature
Surface Mount - Standard Applications (400-5000W):
SMAJ DO-214AC 5.0-440 400W Not Applicable -85° to +302° F
(-65° to +150° C)
P4SMA DO-214AC 5.8-495 400W
SACB DO-214AA 5.0-50 500W
SMBJ DO-214AA 5.0-440 600W
P6SMB DO-214AA 5.8-495 600W
1KSMB DO-214AA 5.8-136 1000W
SMCJ DO-214AB 5.0-440 1500W
1.5SMC DO-214AB 5.8-495 1500W
SMDJ DO-214AB 5.0-170 3000W
5.0SMDJ DO-214AB 12-170 (uni-directional)
12-45 (bi-directional)
5000W
Axial Leaded - Standard Applications (400-5000W):
P4KE DO-41 5.8-495 400W Not Applicable -85° to +302° F
(-55° to +175° C)
SA DO-15 5.0-180 500W
SAC DO-15 5.0-50 500W
P6KE DO-15 5.8-512 600W
1.5KE DO-201 5.8-495 1500W
LCE DO-201 6.5-90 1500W
3KP P600 5.0-220 3000W
5KP P600 5.0-250 5000W
Axial Leaded - High Power:
15KPA P600 17-280 15000W Not Applicable -85° to +302° F
(-55° to +175° C)
20KPA P600 20.0-300 20000W
30KPA P600 28.0-288 30000W
AK6 Radial Lead 58-430 NA 6000A -67° to +347° F
(-55° to +150° C)
AK10 Radial Lead 58-430 NA 10000A
Automotive Applications:
SLD P600 10-24 2200 based on 1μs/150ms pulse NA -85° to +302° F
(-65° to +175° C)
  1. Detailed information about most product series listed here can be found clicking on the series name in the far left column.
  2. For Maximum Clamping Voltage (VC) please refer to electrical characteristics table within each series data sheet
  3. You can get additional TVS Diode selection guidance by perusing Littelfuse's Electronic Products Selection Guide.
  4. All products are Halogen Free
  5. All products are RoHS Compliant

Transient Threats – What Are Transients?

Voltage Transients are defined as short duration surges of electrical energy and are the result of the sudden release of energy previously stored or induced by other means, such as heavy inductive loads or lightning. In electrical or electronic circuits, this energy can be released in a predictable manner via controlled switching actions, or randomly induced into a circuit from external sources.

Repeatable transients are frequently caused by the operation of motors, generators, or the switching of reactive circuit components. Random transients, on the other hand, are often caused by Lightning and Electrostatic Discharge (ESD). Lightning and ESD generally occur unpredictably, and may require elaborate monitoring to be accurately measured, especially if induced at the circuit board level. Numerous electronics standards groups have analyzed transient voltage occurrences using accepted monitoring or testing methods. The key characteristics of several transients are shown in the table below.

  VOLTAGE CURRENT RISE-TIME DURATION
Lighting 25kV 20kA 10 μs 1ms
Switching 600V 500A 50 μs 500ms
EMP 1kV 10A 20ns 1ms
ESD 15kV 30A <1ns 100ns

Table 1. Examples of transient sources and magnitude

Characteristics of Transient Voltage Spikes

Transient voltage spikes generally exhibit a "double exponential" wave, as shown below for lightning and ESD.

Figure 1. Lightning Transient Waveform

Figure 2. ESD Test Waveform

The exponential rise time of lightning is in the range 1.2μsec to 10μsec (essentially 10% to 90%) and the duration is in the range of 50μsec to 1000μsec (50% of peak values). ESD on the other hand, is a much shorter duration event. The rise time has been characterized at less than 1.0ns. The overall duration is approximately 100ns.

Why are Transients of Increasing Concern?

Component miniaturization has resulted in increased sensitivity to electrical stresses. Microprocessors for example, have structures and conductive paths which are unable to handle high currents from ESD transients. Such components operate at very low voltages, so voltage disturbances must be controlled to prevent device interruption and latent or catastrophic failures.

Sensitive microprocessors are prevelant today in a wide range of devices. Everything from home appliances, such as dishwashers, to industrial controls and even toys use microprocessors to improve functionality and efficiency.

Most vehicles now also employ multiple electronic systems to control the engine, climate, braking and, in some cases, steering, traction and safety systems.

Many of the sub- or supporting components (such as electric motors or accessories) within appliances and automobiles present transient threats to the entire system.

Careful circuit design should not only factor environmental scenarios but also the potential effects of these related components. Table 2 below shows the vulnerability of various component technologies.

Device Type Vulnerability (volts)
VMOS 30-1800
MOSFET 100-200
GaAsFET 100-300
EPROM 100
JFET 140-7000
CMOS 250-3000
Schottky Diodes 300-2500
Bipolar Transistors 380-7000
SCR 680-1000

Table 2: Range of device vulnerability.

Comparison to Other Diode Technologies:


Diode Class Application Remarks
Conventional Diode, Rectifier Power Control Useful for "steering" high currents; converting AC to DC. Typically found in large packages such as TO-220.
Zener Diode Power Control Useful for regulation of DC voltage in power supplies. Typically found in medium-size to large packages (Axial, TO-220).
Silicon Avalance Diode (SAD), Transient Voltage Suppressor (TVS) Over-Voltage Protection Useful for protecting circuits exposed to high-energy events such as lightning surges or voltage transients from mechanical switching of electrical circuits (EFT). Typically found in medium-size packages (Axial, DO-214).
Diode Array Over-Voltage Protection Diode Arrays fall into the more broad category of Silicon Protection Arrays (SPA), which are targeted for ESD protection. Typically found in small surface-mount packages (SOIC-8, SOT-23, SC-70, etc …)
Shottky Diode Power Control Useful for high-frequency (HF) rectification required for switch-mode power supplies.
Varactor Diode RF Tuning Only known application of diodes that takes advantage of the junction capacitance characteristic.


Comparison by Operating Characteristic:


Diode Class Reverse Breakdown Voltage
(VBR, VZ)
Capacitance (CJ) Remarks
Conventional Diode, Rectifier 800-1500V Very High AC to DC power conversion
Zener Diode Up to 100V Medium to High DC power regulation
Silicon Avalance Diode (SAD), Up to 600V Medium Lightning surge and voltage transient protection
Diode Array Up to 50V Low (< 50pF) ESD protection of high-frequency data circuits


Comparison by Device Construction:


A Schottky diode is formed by a metal to semiconductor junction. Electrically, it conducts by the majority carrier and possesses fast response with lower current-leakage and forward bias voltage (VF). Schottky diodes are widely used in high frequency circuits.

Zener diodes are formed by a heavily doped P-N semiconductor junction. There are two physical effects which can be referred to as a Zener state (Zener effect and Avalanche effect). Zener effect occurs when there is a low reverse voltage applied to the P-N junction which conducts due to quantum effect. Avalanche effect occurs when a larger than 5.5 Volts voltage applied reversely to the PN junction during which the generated electron-hole pair collide with the lattice. Zener diodes based on the Zener effect are widely used as voltage reference sources in electronics circuitry.

A TVS diode is formed by a specially designed P-N semiconductor junction for surge protection. The PN junction is usually coated to prevent premature voltage arcing during non conducting state. When there is a transient voltage event, the TVS diodes conducts to clamp the transient voltage using the Avalanche effect. TVS diodes are widely used as an over voltage circuit protection device in telecommunications, general electronics, and digital consumer markets for lightning, ESD, and other voltage transient protection.

SPA stands for Silicon Protection Arrays. It is an array of integrated PN junctions, SCRs, or other Silicon protection structures packaged in a multi-pin structure. The SPA can be used as a integrated solution for ESD, lightning, and EFT protection for telecommunications, general electronics, and digital consumer markets where multiple protection opportunities exist. For example, it can be used for HDMI, USB, and Ethernet port ESD protection.

TVS Diode Selection Guide

  1. Define Circuit Operating Parameters

    Normal operating voltage type in DC or AC:

    Device Type Required: Uni-drectional Bi-directional Normal operating voltage in volts:

    Maximum transient current (Ipp):

    Maximum clamping voltage (Vc):

    Required peak reverse surge power rating:

    Product mounting type (package):

    Operating temperature:

  2. Narrow TVS Diode Series for the Application

    Please refer to the product selection charts and data sheets within this site, factoring these key parameters:

    Reverse Standoff Voltage (VR):

    The device VR should be equal to, or great than, the peak operating level of the circuit (or part of the circuit) to be protected. This is to ensure that TVS Diode does not clip the circuit drive voltage.

    Peak Pulse Current (IPP):

    The Peak Pulse Current (IPP) identifies the maximum current the TVS Diode can withstand without damage. The required IPP can only be determined by dividing the peak transient voltage by the source impedance. Note that the TVS Diode failure mechanism is a short circuit; if the TVS Diode fails due to a transient, the circuit will still be protected.

    Maximum Clamping Voltage (VC):

    This the peak voltage that will appear across the TVS Diode when subjected to the Peak Pulse Current (IPP), based on 10X1000us exponential waveform. The VC of each TVS Diode is identified in each series data sheet electrical characteristics table.

  3. Verify Ambient Operating Parameters

    Ensure that the application voltage is less than or equal to the device's standoff voltage, and that the operating temperature limits are within those specified by the device.

  4. Verify Device Mounting Style and Dimensions

    Please refer to the dimension drawings contained within the data sheet of each series.

  5. Test the Selected Device in Actual Application

    Please contact Littelfuse if you would like assistance with testing and verifying suitability of a Littelfuse device within your product. We have extensive product testing lab capabilities and technical expertise to assist you.

TVS Diode Glossary

Clamping Device
TVS is a clamping device that limits voltage spikes by low impedance avalanche breakdown of a rugged silicon PN junction. It is used to protect sensitive components from electrical overstress generated by induced lightning, inductive load switching and electrostatic discharge.

Operating Temperature Range
The minimum and maximum ambient operating temperature of the circuit in which a device will be applied. Operating temperature does not allow for the effects of adjacent components, this is a parameter the designer must take into consideration.

Capacitance
The property of a circuit element that permits it to store an electrical charge. In circuit protection, the off-state capacitance is typically measured at 1 MHz with a 2V bias applied.

Reverse Standoff Voltage (VR)
In the case of a uni-directional TVS diode, this is the maximum peak voltage that may be applied in the 'blocking direction' with no significant current flow. In the case of a bi-directional transient, it applies in either direction. It is the same definition as Maximum Off-state Voltage and Maximum Working Voltage.

Breakdown Voltage (VBR)
Breakdown voltage measured at a specified DC test current, typically 1mA. Usually a minimum and maximum is specified.

Peak Pulse Current (IPP)
Maximum pulse current which can be applied repetitively. Usually a 10x1000μs double exponential waveform, but can also be 8x20μs, if stated.

Maximum Clamping Voltage (VC or VCI)
Maximum voltage which can be measured across the protector when subjected to the Maximum Peak Pulse Current.

Peak Pulse Power (PPP)
Expressed in Watts or Kilowatts, for a 1ms exponential transient (see figure 1, page 23) it is IPP multiplied by VCL.