How to be sure a faulty system does not always appear healthy?: Fault manifestability analysis for discrete event and timed systems

How to be sure a faulty system does not always appear healthy? Fault manifestability analysis for discrete event and timed systems

Fault diagnosability (allowing one to determine with certainty whether a given fault has effectively occurred based on the available observations) is a crucial and challenging property in complex system automatic control, which generally requires a high number of sensors, increasing the system cost,...

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Bibliographic Details
Published in:Innovations in systems and software engineering Vol. 16; no. 2; pp. 121 - 142
Main Authors: Dague, Philippe, He, Lulu, Ye, Lina
Format: Journal Article
Language:English
Published: London Springer London 01-06-2020
Springer Verlag
Subjects:
Artificial Intelligence
Computer Applications
Computer Science
S.I. : VeCoS 2018
Software Engineering
Bounded model checking
Real-time systems
Diagnosability and manifestability
SMT
Timed automata
Model-based diagnosis
Online Access:Get full text
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Summary:Fault diagnosability (allowing one to determine with certainty whether a given fault has effectively occurred based on the available observations) is a crucial and challenging property in complex system automatic control, which generally requires a high number of sensors, increasing the system cost, since it is quite a strong property. In this paper, we analyze a new system property called manifestability, that is a weaker requirement on system observations for having a chance to identify on-line faults: that a faulty system cannot always appear healthy. We propose an algorithm with PSPACE complexity to automatically verify it for finite automata, and prove that the problem of manifestability verification itself is PSPACE-complete. The experimental results show the feasibility of our algorithm from a practical point of view. Then, we extend our approach to verify manifestability of real-time systems modeled by timed automata, proving that it is undecidable in general but under some restricted conditions it becomes PSPACE-complete. Finally, we encode this property into an SMT formula, whose satisfiability witnesses manifestability, before presenting experimental results showing the scalability of our approach.
ISSN:1614-5046
1614-5054
DOI:10.1007/s11334-019-00357-z