The FXMAR2102UMX-F106 is a high-performance, low-power, dual-supply, 2-bit voltage translator from ON Semiconductor. This device is designed to address the needs of multi-voltage systems where signal integrity and seamless translation between different voltage domains are crucial.

Key Features

• Bi-Directional Interface: With the capability to translate signals in both directions, this voltage translator is perfect for two-way communication between different system voltage levels.
• Dual-Supply Operation: It operates with dual supply voltage ranges of 1.65V to 3.6V on the A side and 2.3V to 5.5V on the B side, allowing for flexible integration into various system architectures.
• High-Speed Translation: The device supports high-speed signal translation, making it suitable for applications that require fast data transfer rates without compromising signal quality.
• Low On-Resistance: The FXMAR2102UMX-F106 features low on-resistance, which minimizes voltage drop and power dissipation, enhancing overall system efficiency.
• ESD Protection: It comes with robust Electrostatic Discharge (ESD) protection, ensuring the longevity and reliability of the device in harsh electrical environments.

Applications

The FXMAR2102UMX-F106 is ideal for a variety of applications that require voltage level translation, such as:

• Mobile Devices
• Computing Devices
• Consumer Electronics
• Networking Equipment
• Telecommunication Systems

Package and Quality

This voltage translator is offered in a compact UDFN-8 package, making it suitable for space-constrained applications. ON Semiconductor is committed to high quality and reliability, and the FXMAR2102UMX-F106 is no exception, meeting stringent industry standards for performance and durability.

Conclusion

The FXMAR2102UMX-F106 from ON Semiconductor is an essential component for modern electronics that require efficient and reliable voltage level translation. Its dual-supply operation, bi-directional interface, and high-speed capabilities make it a versatile choice for designers looking to bridge the gap between different voltage domains seamlessly.