Maxim Integrated DS1091LUA-066+ Low-Jitter Clock Multiplier

The DS1091LUA-066+ is a precision, low-jitter clock multiplier from Maxim Integrated designed to enhance clock signals for a broad range of applications. This versatile component is engineered to generate a fixed-frequency output clock derived from a clock input source. Its primary function is to multiply the input clock frequency by a pre-programmed multiplier setting, thereby providing a stable and precise output frequency that is essential for synchronous digital systems.

With its spread-spectrum modulation capability, the DS1091LUA-066+ effectively reduces electromagnetic interference (EMI), which can be critical in applications where signal integrity and regulatory compliance are of utmost importance. This feature is particularly beneficial in environments where electronic devices are densely packed or in close proximity to sensitive analog circuits.

The device operates over a wide voltage range of 3.3V, making it compatible with many contemporary digital systems. Its low-jitter performance ensures high-quality signal integrity, which is paramount for high-speed data communication, high-definition video processing, and precise timing applications. The DS1091LUA-066+ is also characterized by its low power consumption, making it an excellent choice for power-sensitive designs.

Housed in an 8-pin µSOP package, the DS1091LUA-066+ is compact and suitable for space-constrained applications. It is designed for ease of integration into existing designs, requiring minimal external components, which simplifies the design process and accelerates time-to-market for products that necessitate a reliable clock source.

Applications for the DS1091LUA-066+ include, but are not limited to, digital video and audio equipment, networking and telecommunications infrastructure, servers, and storage systems. With Maxim Integrated's reputation for quality and reliability, the DS1091LUA-066+ stands out as a robust solution for designers looking to improve system performance by enhancing clock signals.