The DSC1033DI2-050.0000T is a precision silicon MEMS oscillator from Microchip Technology, a leader in microcontroller and analog semiconductors. This high-performance, low-power oscillator is designed to meet the stringent requirements of modern electronic devices, providing a reliable clock source with an output frequency of 50.0000 MHz.

Key Features

• Frequency: The device offers a stable frequency of 50.0000 MHz, which is ideal for applications requiring precise timing solutions.
• Supply Voltage: It operates at a supply voltage ranging from 1.8V to 3.3V, making it versatile for use in a variety of systems with different power requirements.
• Stability: This oscillator provides excellent frequency stability, ensuring consistent performance over a range of environmental conditions.
• Form Factor: The compact 4-SMD, no lead package allows for easy integration into space-constrained applications without sacrificing performance.
• Power Consumption: Designed for energy efficiency, the DSC1033DI2-050.0000T consumes low power, thereby extending the battery life of portable devices.
• Temperature Range: It operates over an industrial temperature range, making it suitable for harsh environments.
• Output Type: The device provides a CMOS output, which is compatible with most digital integrated circuits.

Applications

The DSC1033DI2-050.0000T is ideal for usage in a wide array of applications where precise and dependable clocking is essential. It is particularly well-suited for:

• Networking equipment such as routers, switches, and wireless communication devices.
• Consumer electronics including wearables, smart home devices, and multimedia systems.
• Industrial and automotive systems that require robust and accurate timing under varying conditions.
• Portable medical devices where power efficiency and reliability are crucial.

With its blend of performance, reliability, and versatility, the Microchip Technology DSC1033DI2-050.0000T oscillator is an excellent choice for designers looking to enhance the timing precision and power efficiency of their electronic systems.