The ADIS16260BCCZ is a state-of-the-art angular rate sensor (gyroscope) designed and manufactured by Analog Devices Inc., a leader in high-performance signal processing solutions. This compact sensor is part of the iSensor® product family and is specifically engineered to deliver precise and reliable angular rate measurements in a variety of industrial and instrumentation applications.

Key Features

• Measurement Range: The sensor offers a ±300°/sec dynamic range, providing high accuracy across a wide range of rotational speeds.
• Digital Output: It features a digital I/O SPI-compatible serial interface, which ensures easy integration with microcontrollers and digital systems without the need for analog-to-digital conversion.
• Calibration: Factory-calibrated sensitivity, bias, and axial alignment allow for straightforward usage, reducing the need for complex system-level calibration.
• Power Management: The ADIS16260BCCZ has flexible power management options with a single-supply operation ranging from 3.0V to 3.6V, optimizing power consumption for battery-powered devices.
• Compact Size: Housed in a 9 mm x 9 mm x 3.1 mm LGA package, this gyroscope is optimized for space-constrained applications.

Applications

The versatility of the ADIS16260BCCZ allows it to be used across various industries and applications. It is ideal for platform stabilization, robotics, instrumentation, and motion control systems. Additionally, its robust performance makes it suitable for automotive safety systems, medical devices, and industrial machinery that require precise motion analysis and feedback.

Product Summary

Analog Devices Inc.'s ADIS16260BCCZ is a high-performance, digital angular rate sensor that offers exceptional accuracy and stability. With its comprehensive feature set, it meets the stringent requirements of modern industrial applications. The combination of its small form factor, ease of use, and high reliability makes it an excellent choice for designers who need to incorporate precise rotational sensing capabilities into their systems.