Product Overview: DSC6111ME2A-006.1679T by Microchip Technology

The DSC6111ME2A-006.1679T is a high-performance, precision MEMS oscillator from the reputable manufacturer Microchip Technology. This component is designed to provide a stable and reliable clock source for a variety of electronic applications, including but not limited to communication systems, consumer electronics, industrial controls, and IoT devices.

Key Features

• Frequency: The oscillator operates at a fixed frequency of 6.1679 MHz, which is suitable for a wide range of timing requirements.
• Supply Voltage: It works within a supply voltage range of 1.71V to 3.63V, making it versatile for different power environments and ensuring compatibility with both 1.8V and 3.3V logic levels.
• Stability: The DSC6111 series is known for its excellent stability, with a tight frequency stability of ±25 ppm over the industrial temperature range (-40°C to +85°C).
• Package: The component comes in a compact 4-SMD, no lead package, which allows for efficient use of PCB space and is suitable for high-density mounting.
• Output Type: It provides a CMOS output, ensuring compatibility with most digital circuits.
• Low Power Consumption: Designed for energy efficiency, this oscillator consumes low power, which is crucial for battery-powered and portable devices.
• RoHS Compliant: The product meets RoHS standards, ensuring it is free from hazardous substances and is environmentally friendly.

Applications

The DSC6111ME2A-006.1679T is ideal for applications that require a high-precision, stable timing solution without the need for an external crystal. Its applications include:

• Wireless communication devices
• Portable and wearable technology
• Industrial control systems
• Medical monitoring equipment
• Smart home devices
• Automotive electronics

Overall, the DSC6111ME2A-006.1679T from Microchip Technology is a reliable and efficient choice for designers looking to improve the performance and stability of their electronic systems while minimizing design complexity and component count.