Abstract
By- wire systems have been established for several years in the area of aircraft construction and there are now approaches to utilize this technology in vehicles. The required electronic systems must evidently be available and safe. In the same time the requirements of mass production have to be reached (long life time, long maintainability intervals, low costs, fulfillment of standards). This paper addresses a new automotive architecture approach - based on a time triggered architecture - and a framework for the application design of future by-wire systems in vehicles.
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References
S. Brilliant, J. C. Knight, N. Leveson: „Analysis of faults in an N-version software experiment,“ IEEE Transations on Software Engineering, SE-16(2), February 1990.
E. Dilger et al.: „Towards an Architecture for Safety Related Fault Tolerant Systems in Vehicles“, Proceedings of the ESREL’97 International Conference, June 1997.
E. Dilger, T. Führer, B. Müller, S. Poledna, T. Thurner: „X-By-Wire: Design von verteilten, fehlertoleranten und sicherheitskritischen Anwendungen in modernen Kraftfahrzeugen“, Tagungsband der 17. VDI/VW-Gemeinschaftstagung Systemengineering in der Kfz-Entwicklung, Wolfsburg, 3.12.-5.12.97
M. Fischer, „Entwicklung eines fehlertoleranten TTP-basierten Multi-Level-Schedulers für den 80C167“, master thesis, Institute for Industrial Automation and Software Engineering, University of Stuttgart, Stuttgart, June 1998
W. Fleisch, Th. Ringler, R. Belschner: „Simulation of application software for a TTP real-time subsystem“, European Simulation Multi Conference, May 1997.
B. Hedenetz, R. Belschner, „Brake-by-wire without Mechanical Backup by Using a TTP-Communication Network“, SAE International Congress 1998, SAE 981109.
B. Hedenetz, A. V. Schedl: „Fault Injection and Fault Modeling for a Safety Critical Automotive Communication System“, ESREL 98, Trondheim, Norway, June 1998.
G. Heiner, T. Thurner, „Time-Triggered Architecture for Safety-Related Distributed Real-Time Systems in Transportation Systems“, FTCS-28, June 1998.
J. Karlsson, P. Folkesson, J. Arlat, Y. Crouzet, G. Leber, „Integration and Comparison of Three Physical Fault Injection Techniques“, Predictably Dependable Computing Systems, Springer Verlag 309–329, 1995.
A. Krüger, H. Kopetz, „A Network Controller Interface for a Time-Triggered Protocol“, SAE Symposium on Future Transportation Electronics: Multiplexing and In-Vehicle Networking, SAE, 1995.
H. Kopetz, G. Grünsteidl, „TTP-A Protocol for Fault-Tolerant Real-Time Systems“, IEEE Computer, pages 14–23, January 1994.
Kopetz et al.: „A Prototype Implementation of a TTP/C Controller. Proc. SAE Congress’ 97“, Detroit, Michigan, 1997.
H. Kopetz, „Real-Time Systems-Design Principles for Distributed Real-Time Systems“, Kluwers Academic Publishers, 1997.
H. Kopetz, „The Systematic Design of Embedded Real-Time Systems“, Three day intensive Seminar, Munich, 1996
Markus Krug and Anton V. Schedl: „New Demands for Invehicle Networks“, Proceedings of the 23rd Euromicro Conference„, pp. 601–606, Budapest, Hungary, September 1997.
A. Krüger, „Interface design for Time-Triggered Real-Time System Architectures“, doctor thesis, Institut für Technische Informatik, Vienna University of Technology, 1997.
M. Krug: „Concept and Implementation of a Dependable Automotive Operating System“, doctor thesis, Institut für Technische Informatik, Universität Tübingen, 1998.
A. Krüger, „Interface design for Time-Triggered Real-Time System Architectures“, doctor thesis, Institut für Technische Informatik, Vienna University of Technology, 1997.
Roman Nossal, „An Application-Oriented Methodology for the Development of Real-Time Applications“, doctor thesis, Institut für Technische Informatik, Vienna University of Technology, 1997.
P. Puschner and A. Schedl. „Computing maximum task execution times-a graphbased approach“, Real-time Systems, 13(1):67–91, July 1997
P. Puschner and Alexander Vrchoticky „Problems in Static Worst-Case Execution Time Analysis“, Research Report No. 6/96, Institut für Technische Informatik, Vienna University of Technology, 1996.
SAE, „Class C Application Requirement Considerations“, SAE Recommended Practice J2056/1, SAE, June 1993.
SAE, „Survey of Known Protocols“, SAE Information Report J2056/2, SAE, April 1993.
Scheidler, G. Heiner, R. Sasse, E. Fuchs, H. Kopetz, C. Temple, „Time-Triggered Architecture-(TTA)“, Advances in Information Technologies: The Business Challenge, J.-Y. Roger et al. (Eds.), IOS Press, 1997, pages 758–765.
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Ringler, T., Steiner, J., Belschner, R., Hedenetz, B. (1998). Increasing System Safety for By-Wire Applications in Vehicles by Using a Time Triggered Architecture. In: Ehrenberger, W. (eds) Computer Safety, Reliability and Security. SAFECOMP 1998. Lecture Notes in Computer Science, vol 1516. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-49646-7_19
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DOI: https://doi.org/10.1007/3-540-49646-7_19
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