Universität Bremen  
  FB 3  
  AG BKB > Publikationen > Suche > Deutsch
English
 

Suche nach Veröffentlichungen - Detailansicht

 
Art der Veröffentlichung: Artikel
Autor: Holger Täubig, Udo Frese, Christoph Hertzberg, Christoph Lüth, Stefan Mohr, Elena Vorobev, Dennis Walter
Titel: Guaranteeing Functional Safety: Design for Provability and Computer-Aided Verification
Band: 32
Seite(n): 303 – 331
Zeitschrift: Autonomous Robots
Ausgabe: 3
Erscheinungsjahr: 2012
Abstract / Kurzbeschreibung: When autonomous robots begin to share the human living and working spaces, safety becomes paramount. It is legally required that the safety of such systems is ensured, e.g. by certification according to relevant standards such as IEC61508. However, such safety considerations are usually not addressed in academic robotics. In this paper we report on one such successful endeavour, which is concerned with designing, implementing, and certifying a collision avoidance safety function for autonomous vehicles and static obstacles. The safety function calculates a safety zone for the vehicle, depending on its current motion, which is as large as required but as small as feasible, thus ensuring safety against collision with static obstacles. We outline the algorithm which was specifically designed with safety in mind, and present our verification methodology which is based on formal proof and verification using the theorem prover Isabelle. The implementation and our methodology have been certified for use in applications up to SIL3 of IEC61508 by a certification authority (TÃœV Süd Rail GmbH, Germany). Throughout, issues we recognised as being important for a successful application of formal methods in robotics are highlighted. Moreover, we argue that formal analysis deepens the understanding of the algorithm, and hence is valuable even outside the safety context.
PDF Version: http://www.informatik.uni-bremen.de/agebv/downloads/published/Taubig2012_AR_author.pdf
Schlagworte: collision detection Functional Safety Formal Verification Certification IEC 61508 Braking Model Mathematical Proof
Status: Reviewed
Letzte Aktualisierung: 18. 04. 2012

 Zurück zum Suchergebnis
 
   
Autor: Automatisch generierte Seite
 
  AG BKB 
Zuletzt geändert am: 9. Mai 2023   impressum