Infineon Technologies Tariff Inquiry

AUIRFR5410

AUIRFR5410 Description

The AUIRFR5410 is a high-performance MOSFET P-CH 100V 13A DPAK from Infineon Technologies, a leading manufacturer in the electronics industry. This Single FET is designed for high-power applications and offers excellent performance benefits. With a maximum drain-source voltage (Vdss) of 100V and a continuous drain current (Id) of 13A at 25°C, the AUIRFR5410 is well-suited for demanding applications.

AUIRFR5410 Features

• Technology: MOSFET (Metal Oxide) - Ensures high efficiency and reliability.
• Input Capacitance (Ciss): 760 pF @ 25V - Minimizes input capacitance for faster switching.
• Gate Charge (Qg): 58 nC @ 10V - Reduces switching losses and improves efficiency.
• Power Dissipation: 66W (Tc) - Capable of handling high power dissipation.
• Mounting Type: Surface Mount - Ideal for compact designs and high-density PCB layouts.
• Rds On (Max): 205mOhm @ 7.8A, 10V - Offers low on-resistance for minimal power loss.
• Vgs(th) (Max): 4V @ 250µA - Provides stable and predictable threshold voltage.
• Series: HEXFET® - Known for its high performance and reliability in power applications.

AUIRFR5410 Applications

The AUIRFR5410 is ideal for various high-power applications, including:

1. Power Supplies: Due to its high Vdss and Id ratings, it is suitable for power supply designs.
2. Motor Controls: The low Rds On and high Id make it an excellent choice for motor control applications.
3. Industrial Automation: Its robust performance and high power dissipation capabilities make it suitable for industrial automation systems.

Conclusion of AUIRFR5410

The AUIRFR5410 is a high-performance MOSFET P-CH 100V 13A DPAK from Infineon Technologies, offering excellent technical specifications and performance benefits. Its unique features, such as low input capacitance, low gate charge, and low on-resistance, make it an ideal choice for high-power applications. While it is currently marked as obsolete, it remains a reliable option for applications where high performance and reliability are critical.