Microchip Technology DSC6301CI2CA-024.0000 Crystal Oscillator

The DSC6301CI2CA-024.0000 is a high-quality, low-jitter crystal oscillator designed and manufactured by Microchip Technology, a leading provider of smart, connected, and secure embedded control solutions. This precision oscillator is ideal for a wide range of applications where stable and reliable clock signals are critical for system performance, including telecommunications, networking, data centers, and industrial automation systems.

Key Features

• Frequency: The oscillator operates at a frequency of 24.0000 MHz, providing a precise clock signal for timing-sensitive applications.
• Supply Voltage: It is designed to work with a supply voltage of 1.8V, ensuring compatibility with low-voltage systems and contributing to overall power efficiency.
• Stability: The DSC6301CI2CA-024.0000 offers excellent frequency stability, minimizing timing errors and ensuring consistent performance over a range of environmental conditions.
• Form Factor: The device comes in a compact, industry-standard 4-SMD, no lead package, making it easy to integrate into various circuit designs without taking up significant board space.
• Operating Temperature: It is built to operate over a wide temperature range, typically from -40°C to +85°C, ensuring reliable operation in harsh environments.
• Output Type: The oscillator provides a CMOS output, which is compatible with most digital circuits and offers a low-power, high-speed switching capability.

Applications

The DSC6301CI2CA-024.0000 is versatile and can be used in a multitude of applications, including:

• Portable electronics where power efficiency is key
• Communication systems requiring precise timing
• Industrial controls and automation equipment
• Networking hardware such as routers and switches
• Consumer electronics, including smart devices

With its high performance, reliability, and Microchip's commitment to quality, the DSC6301CI2CA-024.0000 crystal oscillator is an excellent choice for designers and engineers looking to optimize their systems' clocking accuracy and stability.