Maxim Integrated's DS1000-250K Silicon Delay Line

The DS1000-250K from Maxim Integrated is a high-quality, programmable silicon delay line that offers a range of timing solutions for electronic systems. This innovative component is designed to provide precise, stable, and repeatable delays for digital signals, making it an ideal choice for a multitude of applications such as signal processing, timing adjustment, and clock synchronization.

Key Features

• Programmable Delays: The DS1000-250K allows users to program delays from 5 ns up to 250 ns in 5 ns increments, ensuring flexibility and precision in timing design.
• High Accuracy: With a delay accuracy of ±5 ns or ±2% (whichever is greater), this component guarantees reliable performance for critical timing applications.
• Low Power Consumption: Designed with energy efficiency in mind, the DS1000-250K operates with a low power consumption, making it suitable for power-sensitive designs.
• Voltage Flexibility: The device can be powered by a wide range of supply voltages from 4.75V to 5.25V, providing compatibility with various system voltages.
• Temperature Stability: It maintains consistent delay times over the entire industrial temperature range of -40°C to +85°C, ensuring reliable operation in diverse environmental conditions.
• Compact Form Factor: The DS1000-250K is available in a small 8-pin DIP or SO package, making it easy to integrate into space-constrained designs.

Applications

The versatility of the DS1000-250K makes it an excellent choice for a wide array of applications, including:

• Network synchronization
• Signal buffering and timing adjustment
• Glitch and spike elimination
• Edge-triggered circuitry timing
• Serial-to-parallel data conversion timing

Maxim Integrated's commitment to quality and innovation is evident in the DS1000-250K silicon delay line. With its programmable nature, high accuracy, and robust performance, this component stands out as a go-to solution for designers looking to enhance the timing precision of their electronic systems.