The DS1091LUA-172/V+T is a versatile, low-jitter, spread-spectrum clock oscillator designed and manufactured by Maxim Integrated. This high-performance component is engineered to enhance system performance by reducing electromagnetic interference (EMI) in electronic systems. It is particularly suitable for applications where noise reduction is critical, such as in computing, consumer electronics, and telecommunications equipment.

Key Features

• Spread Spectrum Clock Output: The device employs spread-spectrum technology to distribute the energy of the fundamental frequency over a wider bandwidth, thereby reducing EMI at any single frequency.
• Frequency Range: The DS1091LUA-172/V+T operates at a frequency of 172MHz, making it suitable for high-speed applications.
• Low Jitter: The device provides low clock jitter, which is essential for maintaining signal integrity in high-speed communication and ensuring reliable operation of digital circuits.
• Supply Voltage: It operates with a supply voltage of 3.3V, which is a common voltage level for many digital systems, ensuring compatibility with a wide range of applications.
• Package: The oscillator is available in an 8-pin µSOP package, which is compact and suitable for space-constrained applications.
• Temperature Range: With an operating temperature range from -40°C to +85°C, the DS1091LUA-172/V+T is designed to perform reliably in a variety of environments.

Applications

The DS1091LUA-172/V+T is an ideal choice for use in a range of applications where minimizing EMI is important. These include:

• Computing systems such as servers, desktops, and laptops
• Consumer electronics including gaming consoles, TVs, and audio equipment
• Networking equipment like routers, switches, and modems
• Telecommunication systems including base stations and networking hardware

Maxim Integrated's commitment to quality ensures that the DS1091LUA-172/V+T meets the stringent requirements of modern electronic systems, offering designers a reliable and effective solution for managing clock signals and EMI challenges.