Microchip Technology's DSA6111JL2B-024.0000VAO Precision Oscillator

The DSA6111JL2B-024.0000VAO is a cutting-edge precision oscillator from Microchip Technology, a leader in the field of smart, connected, and secure embedded control solutions. This high-performance product is part of Microchip's comprehensive line of timing and frequency control devices, designed to meet the rigorous demands of modern electronic systems.

Key Features:

• Frequency: The oscillator operates at a stable frequency of 24.0000 MHz, which is ideal for applications requiring a precise clock signal.
• Supply Voltage: It is designed to work with a supply voltage of 3.3V, making it compatible with a wide range of electronic devices and systems.
• Stability: The DSA6111JL2B-024.0000VAO boasts excellent stability, which ensures reliable performance even under varying environmental conditions.
• Form Factor: This oscillator comes in a compact surface-mount package, allowing for easy integration into space-constrained applications.
• Low Jitter: The device features low phase jitter, which is critical for high-speed digital communications, data conversion, and other applications where signal integrity is paramount.
• Temperature Range: Its operational temperature range suits industrial applications, ensuring consistent performance across diverse operating conditions.

Applications:

The DSA6111JL2B-024.0000VAO is versatile and can be used in various applications, including but not limited to:

• Networking equipment such as routers, switches, and wireless communication systems
• High-speed data transmission where signal integrity is crucial
• Industrial control systems requiring precise timing for process control
• Consumer electronics where consistent performance is needed

Microchip Technology's commitment to quality ensures that the DSA6111JL2B-024.0000VAO oscillator is manufactured to the highest standards. It is an excellent choice for designers and engineers looking for a reliable and precise timing solution to enhance the performance and stability of their electronic systems.