ON Semiconductor MC10EL07DT - 5V ECL/PECL to TTL Translator

The ON Semiconductor MC10EL07DT is a high-performance, 5V ECL/PECL to TTL translator integrated circuit designed for applications requiring the translation of high-speed differential PECL signals to TTL signal levels. This device is part of ON Semiconductor's 10EL series, which is renowned for its high-speed operation and reliability.

Key Features

• High Speed: The MC10EL07DT offers fast propagation delays, typically 2.5 ns, making it suitable for high-frequency signal processing and clock distribution applications.
• Differential PECL Inputs: This device can handle differential PECL inputs, which are less susceptible to noise and provide improved signal integrity over single-ended signals.
• TTL Compatible Outputs: Outputs are TTL compatible, allowing for easy integration with TTL logic families.
• Power Supply: The translator operates with a 5V power supply, which is compatible with standard TTL operating voltages.
• Temperature Range: It is designed to perform reliably over an extended industrial temperature range, from -40°C to +85°C, accommodating various environmental conditions.
• Package: The device is available in a space-saving SOIC-8 package, which is suitable for compact PCB layouts.

Applications

The MC10EL07DT is ideal for use in a range of applications where signal translation from PECL to TTL is required. This includes:

• High-speed data communication equipment
• Clock distribution networks
• Telecommunications infrastructure
• Test and measurement systems
• Computing and data storage systems

Conclusion

The ON Semiconductor MC10EL07DT is a versatile and high-performance solution for converting 5V ECL/PECL signals to TTL logic levels. Its fast propagation times, differential input capability, and TTL compatibility make it an excellent choice for designers looking to bridge between these two logic families while maintaining signal integrity and speed. The industrial temperature range and compact packaging further enhance its applicability across various high-speed digital applications.