The DSC1001DI1-024.0000T is a cutting-edge silicon MEMS oscillator from Microchip Technology, a leading provider of smart, connected, and secure embedded control solutions. This high-performance, low-power oscillator is designed to deliver exceptional frequency stability and reliability for a wide range of electronic applications. With its compact size and robust feature set, the DSC1001 series represents a significant advancement in timing solutions, offering an ideal alternative to traditional crystal oscillators.

Key Features

• Frequency: This device provides a stable frequency output of 24.0000 MHz, crucial for applications requiring precise timing.
• Supply Voltage: It operates at a supply voltage of 1.8V, making it suitable for low-power applications and helping to reduce overall power consumption.
• Stability: The oscillator boasts excellent frequency stability, ensuring reliable performance under varying environmental conditions.
• Package: The DSC1001DI1-024.0000T is offered in a compact industry-standard 4-SMD footprint, which is highly advantageous for space-constrained designs.
• Temperature Range: It operates over an industrial temperature range, making it versatile for use in harsh environments.
• Output Type: The device provides a CMOS output, which is compatible with a wide range of digital circuits.

Applications

The versatility of the DSC1001DI1-024.0000T makes it suitable for a diverse array of applications. It is particularly well-suited for use in:

• Consumer Electronics
• Networking Equipment
• Wireless Communication Devices
• Internet of Things (IoT) Products
• Industrial Systems
• Portable Battery-Powered Devices

Quality and Reliability

Microchip Technology is committed to providing products that meet the highest standards of quality and reliability. The DSC1001DI1-024.0000T is manufactured in state-of-the-art facilities, ensuring that each oscillator meets Microchip's stringent requirements for performance and longevity. Customers can trust this product to deliver consistent, dependable results in their applications.