The ON Semiconductor MC100EP35D is a high-speed differential clock designed to deliver precise clock signals with minimal skew and jitter. This device is an integral component for a range of high-performance applications where timing accuracy is critical. The MC100EP35D is part of ON Semiconductor's EP35 series, known for its reliability and performance in demanding environments.

Key Features

• High Speed: The MC100EP35D operates at exceptional clock frequencies, making it suitable for high-speed digital systems.
• Differential Outputs: It provides differential PECL outputs, ensuring reduced noise and improved signal integrity.
• Temperature Range: This device is operational over a wide temperature range, making it versatile for different operating conditions.
• Power Supply: The MC100EP35D is designed for a 3.3V power supply, which is a standard voltage in digital systems, offering ease of integration.
• Package: It is available in an 8-lead SOIC package, which is compact and suitable for space-constrained applications.

Applications

The MC100EP35D is ideal for a variety of applications, including:

• Clock distribution networks
• Telecommunications and data communications
• PLL circuits
• Servers and data centers
• Test and measurement equipment

Performance and Quality

ON Semiconductor is known for its commitment to quality and the MC100EP35D is no exception. This device is built to offer robust performance while maintaining signal fidelity. It is designed to minimize signal skew and provide a stable clock distribution network, which is essential for maintaining the integrity of high-speed digital signals.

Conclusion

The MC100EP35D from ON Semiconductor is an excellent choice for systems that require precise clock signals. With its high-speed capabilities, differential output, and reliable operation across various temperatures, it stands out as a robust solution for advanced clocking requirements. Whether for telecommunications, data communications, or server applications, the MC100EP35D is designed to enhance system performance and stability.