ON Semiconductor MC10EP31DG – High-Speed Differential ECL D Flip-Flop

The MC10EP31DG is a masterfully engineered differential ECL D flip-flop from ON Semiconductor, designed to deliver exceptional performance in high-speed digital circuits. This advanced logic device is ideal for applications that demand fast edge rates and precise timing, such as data communication, telecommunication, and high-performance computing systems.

Key Features

• High-Speed Performance: With a typical propagation delay of only 175 ps, the MC10EP31DG ensures swift data processing and timing-critical operations.
• Differential Design: The differential inputs provide improved noise immunity, making this device suitable for environments with high levels of electrical interference.
• PECL Mode Operation: Optimized for PECL mode operation, it can be interfaced with other ECL components, allowing for seamless integration in existing designs.
• Single Supply Voltage: The device operates on a single 3.3V or 5V supply, simplifying power management within the system.
• Temperature Range: It is designed to operate over a broad temperature range, from -40°C to +85°C, ensuring reliability in various operating conditions.
• Functional Versatility: The MC10EP31DG features a master-slave flip-flop configuration, which can be used in frequency division or as a basic memory element.

Package and Quality

The device is housed in an 8-pin SOIC package, offering a compact footprint for space-constrained applications. The MC10EP31DG is also part of ON Semiconductor's commitment to high-quality standards, ensuring robust performance and longevity.

Applications

ON Semiconductor's MC10EP31DG is versatile enough to be utilized in a wide array of applications, including:

• High-speed data transmission systems
• Precision timing circuits
• Phase-locked loops (PLLs)
• Serial and parallel data processing
• Networking equipment such as routers and switches

With its combination of speed, precision, and reliability, the MC10EP31DG is a top choice for designers looking to optimize their high-speed digital systems.