NXP PCA82C200P Stand-Alone CAN Controller

The PCA82C200P is a high-performance, stand-alone Controller Area Network (CAN) controller developed by NXP Semiconductors. This device is designed to handle serial communication tasks in automotive and industrial applications, allowing for efficient networking and communication between multiple microcontrollers within a system.

Key Features:

• Compatibility: Fully compatible with the CAN 2.0B protocol, the PCA82C200P supports both standard (11-bit identifier) and extended (29-bit identifier) frames, making it a versatile choice for a wide range of CAN-based networks.
• Communication Speed: Capable of transfer rates up to 1 Mbps, this controller is suitable for high-speed data exchange, ensuring timely and reliable communication within a network.
• Error Handling: Equipped with advanced error detection and confinement capabilities, the PCA82C200P enhances network reliability by identifying and managing errors effectively.
• Flexible Interface: The device offers a simple parallel interface to a host microcontroller, allowing for straightforward integration into existing systems.
• Low Power Consumption: Designed with power efficiency in mind, the PCA82C200P features a low-power standby mode, reducing energy consumption when the network is inactive.

Applications:

The PCA82C200P is ideal for a variety of applications, including:

• Automotive control systems such as engine management, ABS, and airbags
• Industrial automation and control systems
• Medical equipment
• Building automation

Package and Availability:

This CAN controller is available in a DIP-28 (Dual In-line Package) format, providing a convenient solution for through-hole mounting on printed circuit boards. Its robust design ensures reliable operation even in harsh environments.

With its comprehensive feature set and strong track record in the automotive and industrial markets, the NXP PCA82C200P CAN controller is a proven solution for anyone looking to implement a CAN network with minimal complexity and maximum efficiency.