The DSC6023JE1B-01D8 is a cutting-edge, low-power, precision MEMS oscillator designed and manufactured by Microchip Technology, a global leader in microcontroller, mixed-signal, analog, and Flash-IP solutions. This compact and reliable component is ideal for replacing traditional crystal oscillators in a wide range of electronic applications.

Key Features

• Frequency Range: It operates at a frequency of 1.8 MHz, providing a stable and precise clock signal that is essential for digital electronics.
• Supply Voltage: The DSC6023 series supports a supply voltage range from 1.6V to 3.6V, making it versatile for various applications and power conditions.
• Low Power Consumption: It is designed for energy efficiency, which is crucial for battery-powered devices, with typical current consumption as low as 2.0 mA.
• Stability: The oscillator offers excellent frequency stability, which is vital for maintaining the performance and reliability of the system it is integrated into.
• Form Factor: The device comes in an ultra-small 2.5 x 2.0 mm package, which is highly beneficial for space-constrained applications.
• Operating Temperature Range: It can operate within a wide temperature range of -40°C to +85°C, ensuring functionality under various environmental conditions.
• Output Type: The DSC6023JE1B-01D8 provides a CMOS output, which is compatible with most digital circuits.

Applications

With its robust feature set, the DSC6023JE1B-01D8 is suitable for a variety of applications, including but not limited to portable electronics, wearables, Internet of Things (IoT) devices, healthcare monitoring systems, industrial controls, and consumer electronics. Its low power consumption and small footprint make it particularly well-suited for mobile and handheld devices.

Quality and Reliability

Microchip Technology is known for its commitment to quality and reliability, and the DSC6023JE1B-01D8 is no exception. This MEMS oscillator is designed to meet stringent industry standards, ensuring long-term performance and stability for critical applications.