The DSC1001BL5-026.6500T is a high-performance silicon MEMS oscillator from Microchip Technology, a leading provider of smart, connected, and secure embedded control solutions. This precision oscillator is designed to meet the needs of a wide range of applications, offering a compelling alternative to traditional crystal oscillators (XO) with its robustness and reliability.

Key Features

• Frequency Range: The device operates at a fixed frequency of 26.6500 MHz, which is suitable for various applications, including but not limited to embedded systems, telecommunications, and consumer electronics.
• Supply Voltage: It features a supply voltage (Vdd) of 1.8V to 3.3V, providing flexibility for different power requirements and helping to ensure compatibility with a wide range of circuits.
• Stability: The DSC1001BL5-026.6500T offers excellent frequency stability, making it a reliable choice for applications that require consistent performance over time and under varying environmental conditions.
• Package Type: This oscillator comes in a compact 4-SMD, no-lead package, allowing for efficient use of board space in space-constrained designs.
• Operating Temperature: It is designed to operate over an industrial temperature range, ensuring reliable performance across diverse operating conditions.
• Low Power Consumption: As a MEMS-based device, it consumes less power compared to traditional crystal oscillators, contributing to the energy efficiency of the overall system.

Applications

The DSC1001BL5-026.6500T is ideal for a variety of applications, including:

• Internet of Things (IoT) devices
• Wearable technology
• Wireless communication systems
• Networking equipment
• Industrial control systems
• Consumer electronics

Quality and Reliability

Microchip Technology is known for its commitment to quality and longevity. The DSC1001BL5-026.6500T is manufactured to the highest standards, ensuring that it meets the rigorous demands of modern electronic applications. Customers can trust this product for its consistent performance and durability.