Multiplexed networks for embedded systems CAN, LIN, Flexray, Safe-by-Wire ...
Multiplexed networks are essential for the unified, efficient and cost-effective exchange of electronic information within embedded component systems. This is especially important in automotive manufacturing as vehicles become increasingly reliant on robust electronic networks and systems for improv...
| Main Author: | |
|---|---|
| Format: | eBook |
| Language: | English |
| Published: |
Chichester, England
Wiley
2007
|
| Subjects: | |
| Online Access: | |
| Collection: | O'Reilly - Collection details see MPG.ReNa |
Table of Contents:
- 9 Safe-by-Wire
- 9.1 A little history
- 9.2 Safe-by-Wire Plus
- 9.3 Some words of technology
- 10 Audio-video buses
- 10.1 I2C Bus
- 10.2 The D2B (Domestic digital) bus
- 10.3 The MOST (Media oriented systems transport) bus
- 10.4 The IEEE 1394 bus or 'FireWire'
- 11 RF communication and wireless mini-networks
- 11.1 Radio-frequency communication: internal
- 11.2 Radio-frequency communication: external
- 11.3 Wireless networks
- Conclusion
- Part C Appendices
- Appendix A. CiA (CAN in Automation)
- Appendix B. Essential references
- Appendix C. Further reading
- Appendix D. Useful addresses
- Index
- Last Page
- Includes bibliographical references and index
- 4.4 Optical media
- 4.5 Electromagnetic media
- 4.6 Pollution and EMC conformity
- 5 Components, applications and tools for CAN
- 5.1 CAN components
- 5.2 Applications
- 5.3 Application layers and development tools for CAN
- 6 Time-triggered protocols
- FlexRay
- 6.1 Some general remarks
- 6.2 Event-triggered and Time-triggered Aspects
- 6.3 TTCAN
- Time-triggered communication on CAN
- 6.4 Towards high-speed, X-by-Wire and redundant systems
- 6.5 FlexRay
- Part B New multiplexed bus concepts: LIN, FlexRay, Fail-safe SBC, Safe-by-Wire
- 7 LIN
- Local Interconnect Network
- 7.1 Introduction
- 7.2 Basic Concept of the LIN 2.0 Protocol
- 7.3 Cost and market
- 7.4 Conformity of LIN
- 7.5 Examples of components for LIN 2.0
- 8 Think 'Bus', think 'Fail-safe SBC', 'Gateways' . .
- 8.1 Fail-safe SBCs: their multiple aspects and reasons for using them
- 8.2 The strategy and principles of re-use
- 8.3 Demo board
- 8.4 Gateways
- 8.5 Managing the application layers
- Cover
- Contents
- Preface
- Acknowledgements
- Part A CAN: from concept to reality
- 1 The CAN bus: general
- 1.1 Concepts of bus access and arbitration
- 1.2 Error processing and management
- 1.3 Increase your word power
- 1.4 From concept to reality
- 1.5 Historical context of CAN
- 1.6 Patents, licences and certification
- 2 CAN: its protocol, its properties, its novel features
- 2.1 Definitions of the CAN protocol: 'ISO 11898-1'
- 2.2 Errors: their intrinsic properties, detection and processing
- 2.3 The rest of the frame
- 2.4 CAN 2.0B
- 3 The CAN physical layer
- 3.1 Introduction
- 3.2 The 'CAN bit'
- 3.3 Nominal bit time
- 3.4 CAN and signal propagation
- 3.5 Bit synchronization
- 3.6 Network speed
- 4 Medium, implementation and physical layers in CAN
- 4.1 The range of media and the types of coupling to the network
- 4.2 High-Speed CAN, from 125 kbit s-1 to 1Mbit s-1: ISO 11898-2
- 4.3 Low speed CAN, from 10 to 125 kbit s-1