The DSC1001CI2-027.0000T is a high-performance, precision silicon MEMS oscillator manufactured by Microchip Technology, a leader in the field of smart, connected, and secure embedded control solutions. This product is designed to provide a stable and reliable clock source for a wide range of electronic applications.

Key Features

• Frequency: The device offers a fixed output frequency of 27.0000 MHz, which is ideal for applications requiring a stable frequency source.
• Package: Housed in a compact industry-standard 4-pin ceramic package (2.5mm x 2.0mm), the DSC1001CI2-027.0000T is designed for space-constrained applications.
• Stability: It provides excellent temperature stability and low jitter performance, ensuring reliable operation under varying environmental conditions.
• Supply Voltage: The oscillator operates at a supply voltage of 1.8V to 3.3V, accommodating a range of power supply requirements.
• Output Type: The DSC1001CI2-027.0000T features a CMOS output, offering compatibility with most digital circuits.
• Low Power Consumption: This device is optimized for low power consumption, making it suitable for battery-powered and portable devices.

Applications

The DSC1001CI2-027.0000T is versatile and can be used in various applications, including:

• Consumer electronics such as wearables and smart home devices
• Industrial and IoT devices requiring precise timing
• Telecommunication infrastructure
• Automotive systems that demand robust performance
• Medical equipment with strict timing requirements

Quality and Reliability

Microchip Technology is committed to delivering products that meet the highest standards of quality and reliability. The DSC1001CI2-027.0000T is no exception, undergoing rigorous testing to ensure it meets the stringent requirements for industrial and commercial use.

For designers and engineers looking for a reliable clock solution, the DSC1001CI2-027.0000T from Microchip Technology offers a blend of performance, stability, and versatility, making it an excellent choice for a multitude of time-sensitive applications.