The DSC1033DI1-064.0000 is a high-performance, low-power, precision silicon MEMS oscillator from Microchip Technology, a leading manufacturer of microcontroller, mixed-signal, analog, and Flash-IP solutions. This product is designed to deliver exceptional stability and reliability for a wide range of applications that require precise timekeeping and clock synchronization.

Key Features

• Frequency: The oscillator operates at a stable frequency of 64.0000 MHz, providing a precise timing solution for your application.
• Supply Voltage: It is designed to work with a supply voltage of 1.8V, making it suitable for low-power applications.
• Output Type: The device offers a CMOS output, ensuring compatibility with most digital circuits.
• Packaging: This component is available in a compact 4-SMD, no lead package, allowing for efficient use of PCB space.
• Temperature Stability: The oscillator maintains excellent performance over a wide temperature range, ensuring consistent operation under varying environmental conditions.
• Low Jitter: The DSC1033DI1-064.0000 is engineered to provide low phase jitter, which is critical for high-speed digital communications and data transfer.

Applications

The DSC1033DI1-064.0000 is versatile and can be used in numerous applications, including:

• Networking equipment such as routers, switches, and wireless communication devices
• Consumer electronics including high-definition televisions, digital cameras, and gaming consoles
• Industrial systems for automation and control
• Medical devices that require precise timing for diagnostics and treatment
• Portable battery-powered devices where power efficiency is paramount

Quality and Reliability

Microchip Technology is known for its commitment to quality, and the DSC1033DI1-064.0000 is no exception. It is manufactured to meet rigorous standards, ensuring high reliability and performance for the lifetime of your product. With its robust design and advanced MEMS technology, this oscillator is an excellent choice for designers looking to enhance the performance and stability of their electronic systems.