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Serial communication by means of CAN is being used more and more for data transfer between in-vehicle control units to link components of the drive train, body electronics and mobile communication electronics. In order to design distributed electronic systems, software engineers today must not only develop the application software but also supply the communication software to handle the communication hardware, thereby reinventing the wheel with each new application software package. This procedure is inefficient as it leads to hardly reusable special solutions. To avoid incompatibilities between the modules of a distributed system a lot of additional coordination work must be done during the design phase. As a consequence, each new software package is faced with additional costs for the indispensible tests of the communication software. This paper describes a network architecture that has been designed for CAN systems.

A recent extension of the Controller Area Network (CAN) protocol allows an efficient mapping of the SAE J1850 data link messages defined by SAE J2178 into the CAN message format. Compatibility between J1850 and CAN at the message header level allows designers to use the same messages and overall communications strategy for both today's medium speed SAE Class B links and tomorrow's high speed Class C bus applications. This paper presents a proposed mapping of SAE J2178 messages into extended format CAN messages and explains the benefits of this approach for vehicle systems developers.

Signals in Automotive Communication Networks often represent safety relevant information. Therefore, automotive network protocols provide multiple powerful mechanisms for error detection and for error reporting. The objective is to ensure that on average less than one undetected error occurs during the lifetime of a vehicle. This places an upper bound on the residual error probability of the communication network. The determination of this residual error probability requires new methods in order to account for the interaction of the various error detection mechanisms. This paper presents an analysis method that has been developed for the investigation of the CAN protocol. This comprehensive investigation distinguishes two types of errors that contribute most significantly to the residual error probability of the CAN protocol. Errors of one type transform stuffbits into information bits or vice versa, and are related to the use of variable bit stuffing.

A significant portion of communication in Automotive Networks consists of signals, which are vital to the safety of the vehicle. In addition to requirements resulting from the actual transfer of information an Automotive Communication Protocol has to incorporate properties which ensure operational safety even in presence of errors. Based upon a discrimination into reversible errors and irreversible failures, defect nodes have to be determined and subsequently disconnected from the network. In this paper proper schemes for error detection, report, recovery and confinement are presented.