The identifiability problem for repairable systems subject to competing risks

Within reliability theory, identifiability problems arise through competing risks. If we have a series system of several components, and if that system is replaced or repaired to as good as new on failure, then the different component failures represent competing risks for the system. It is well kno...

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Bibliographic Details
Published in:Advances in applied probability 2004-09, Vol.36 (3), p.774-790
Main Authors: Bedford, Tim, Lindqvist, Bo H.
Format: Article
Language:English
Subjects:
37A30
60G35
60J27
60K10
90B25
Borel sets
Competing risks
Epics
Ergodic theory
ergodicity
Failure
General Applied Probability
Identifiability
joint survival distribution
marked point process
Markov analysis
Markov chain
Markov chains
Parametric models
Poisson process
Probability
Probability distributions
Reliability
Reliability functions
Remarriage
Studies
System failures
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Summary:Within reliability theory, identifiability problems arise through competing risks. If we have a series system of several components, and if that system is replaced or repaired to as good as new on failure, then the different component failures represent competing risks for the system. It is well known that the underlying component failure distributions cannot be estimated from the observable data (failure time and identity of failed component) without nontestable assumptions such as independence. In practice many systems are not subject to the ‘as good as new’ repair regime. Hence, the objective of this paper is to contrast the identifiability issues arising for different repair regimes. We consider the problem of identifying a model within a given class of probabilistic models for the system. Different models corresponding to different repair strategies are considered: a partial-repair model, where only the failing component is repaired; perfect repair, where all components are as good as new after a failure; and minimal repair, where components are only minimally repaired at failures. We show that on the basis of observing a single socket, the partial-repair model is identifiable, while the perfect- and minimal-repair models are not.
ISSN:0001-8678
1475-6064
DOI:10.1239/aap/1093962233