The DSC6311JE1EA-027.0000T is a high-performance, low-jitter MEMS oscillator designed and manufactured by Microchip Technology, a leading provider of smart, connected, and secure embedded control solutions. This precision oscillator is part of Microchip's comprehensive timing solutions portfolio and is ideal for a wide range of applications in various industries, including telecommunications, consumer electronics, automotive, and industrial systems.

Key Features

• Frequency: This device offers a stable output frequency of 27.0000 MHz, which is crucial for systems requiring precise timing.
• Supply Voltage: It operates at a supply voltage of 1.8V, making it suitable for low-power applications and compatible with modern microcontrollers and FPGAs.
• Low Jitter: The DSC6311JE1EA-027.0000T boasts exceptionally low jitter performance, ensuring reliable and stable operation in applications where timing accuracy is paramount.
• Temperature Stability: The device is designed to maintain its performance across a wide temperature range, ensuring consistent operation under varying environmental conditions.
• Packaging: It comes in a compact, surface-mount package that is easy to integrate into various PCB designs, saving space and simplifying the manufacturing process.
• Long-term Reliability: Utilizing MEMS technology, this oscillator provides excellent long-term reliability compared to traditional crystal oscillators.

Applications

The DSC6311JE1EA-027.0000T is versatile and can be used in a multitude of applications, such as:

• Networking equipment like routers, switches, and network interface cards
• Consumer electronics including smart TVs, gaming consoles, and wearable devices
• Industrial systems for process control and automation
• Automotive electronics for infotainment and navigation systems
• Internet of Things (IoT) devices requiring accurate timing for communication protocols

Overall, the DSC6311JE1EA-027.0000T from Microchip Technology is a robust and reliable choice for designers looking to enhance the performance and stability of their electronic systems.