Manufacturer Part Number
MIC5020YM
Manufacturer
microchip-technology
Introduction
The MIC5020YM is a high-performance, low-side, N-channel MOSFET gate driver from Microchip Technology. It is designed to provide reliable and efficient control of power MOSFET gates in a wide range of applications, including switch-mode power supplies, motor drives, and other power electronics systems.
Product Features and Performance
Operates from an 11V to 50V supply voltage
Accepts TTL/CMOS-compatible logic inputs
Provides a single, non-inverting gate driver output
Features fast rise and fall times of 700ns and 500ns, respectively
Supports operating temperatures from -40°C to +85°C
Available in an 8-pin SOIC package
Product Advantages
Robust and reliable performance in high-power applications
Efficient gate driving for improved system efficiency
Compact surface-mount package for space-constrained designs
Wide operating voltage range for versatile usage
Key Reasons to Choose This Product
Proven Microchip Technology reliability and quality
Optimized for high-performance power electronics applications
Easy to integrate into various circuit designs
Cost-effective solution for gate driver requirements
Quality and Safety Features
Designed and manufactured to Microchip's rigorous quality standards
Undergoes extensive testing and screening to ensure reliability
Complies with relevant safety and environmental regulations
Compatibility
The MIC5020YM is compatible with a wide range of power MOSFET devices and can be used in various power electronics applications.
Application Areas
Switch-mode power supplies
Motor drives and control systems
Industrial automation and control equipment
Renewable energy systems
Automotive electronics
Product Lifecycle
The MIC5020YM is an active product in our website's sales team's portfolio. There are no immediate plans for discontinuation. However, customers are advised to consult our website's sales team for the latest product availability and lifecycle information, as well as for any potential alternative or equivalent models.