The ST20NE20 is a state-of-the-art N-Channel enhancement mode power MOSFET designed and manufactured by STMicroelectronics, a global leader in semiconductor technology. This power MOSFET is a testament to STMicroelectronics' commitment to providing advanced energy-efficient solutions for a wide range of applications.

Key Features

• Voltage and Current Ratings: With a drain-source voltage (V_DS) of 200V and a continuous drain current (I_D) of 20A, the ST20NE20 is capable of handling high-power applications with ease.
• Low On-Resistance: The device boasts an extremely low on-resistance (R_DS(on)) which minimizes conduction losses, improving overall efficiency and performance in electronic circuits.
• High-Speed Switching: Designed for fast switching applications, the ST20NE20 offers reduced switching losses, making it ideal for high-frequency power converters and motor control systems.
• Gate Charge: The optimized gate charge (Q_G) ensures that the power MOSFET can be driven at lower voltages, reducing the power required to switch the device on and off.
• Package: Housed in a TO-220 package, the ST20NE20 is designed for easy integration into a variety of circuit designs, providing a balance between performance and practicality.

Applications

The ST20NE20 is suited for a diverse range of applications where high voltage and current handling capabilities are required. These include:

• Switch Mode Power Supplies (SMPS)
• DC-to-DC converters
• Motor Control Systems
• Power Management Functions
• Automotive and Industrial Applications

Quality and Reliability

STMicroelectronics ensures that the ST20NE20, like all of its products, meets the highest quality and reliability standards. The device undergoes rigorous testing and quality control measures to ensure it performs to the specifications under a wide range of conditions.

Whether you are designing power supplies, motor controllers, or other power-intensive applications, the ST20NE20 offers a robust and efficient solution that can help optimize performance and reduce energy consumption.