ON Semiconductor MC10E196FNR2 Product Overview

The MC10E196FNR2 is a high-performance 5-bit binary ripple counter, expertly designed and manufactured by ON Semiconductor. This device is part of the 10E series, which is renowned for its ECLinPS MAX™ family of high-speed, low-power integrated circuits. The MC10E196FNR2 is specifically created to address the needs of high-speed counting applications in the telecommunications, computing, and data processing industries.

Key Features

• High-Speed Performance: The counter operates with exceptional speed, capable of handling frequencies that are essential for modern high-speed systems.
• Low Power Consumption: Despite its speed, the device is designed to consume minimal power, making it suitable for power-sensitive applications.
• 5-Bit Binary Count: The counter provides a 5-bit binary count sequence, offering a range of count states for various counting requirements.
• Asynchronous Master Reset: This feature allows for the counter to be quickly and effectively reset to the zero state, ensuring reliable operation and ease of use.
• Differential PECL Outputs: The outputs of the MC10E196FNR2 are differential PECL (Positive Emitter-Coupled Logic) which provides improved signal integrity and noise immunity.
• Temperature Range: It operates within an industrial temperature range, ensuring reliable performance under varying environmental conditions.

Applications

• Digital Data Processing
• High-Speed Clock Division
• Frequency Synthesis
• Telecommunications
• Automated Test Equipment

The MC10E196FNR2 is packaged in a 28-lead PLCC (Plastic Leaded Chip Carrier) which provides a compact footprint while allowing for effective heat dissipation. This package is suitable for surface mount technology (SMT), which is beneficial for modern high-density circuit board designs.

With its combination of speed, power efficiency, and robust feature set, the ON Semiconductor MC10E196FNR2 is an ideal solution for designers looking to implement reliable high-speed counting functionality in their next-generation electronic systems.