OPTIMALLY REPLACING MULTIPLE SYSTEMS IN A SHARED ENVIRONMENT

We consider the problem of optimally replacing multiple stochastically degrading systems using condition-based maintenance. Each system degrades continuously at a rate that is governed by the current state of the environment, and each fails once its own cumulative degradation threshold is reached. T...

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Bibliographic Details
Published inProbability in the engineering and informational sciences Vol. 32; no. 2; pp. 179 - 206
Main Authors Abdul-Malak, David T., Kharoufeh, Jeffrey P.
Format Journal Article
LanguageEnglish
Published New York, USA Cambridge University Press 01.04.2018
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Summary:We consider the problem of optimally replacing multiple stochastically degrading systems using condition-based maintenance. Each system degrades continuously at a rate that is governed by the current state of the environment, and each fails once its own cumulative degradation threshold is reached. The objective is to minimize the sum of the expected total discounted setup, preventive replacement, reactive replacement, and downtime costs over an infinite horizon. For each environment state, we prove that the cost function is monotone nondecreasing in the cumulative degradation level. Additionally, under mild conditions, these monotonicity results are extended to the entire state space. In the case of a single system, we establish that monotone policies are optimal. The monotonicity results help facilitate a tractable, approximate model with state- and action-space transformations and a basis-function approximation of the action-value function. Our computational study demonstrates that high-quality, near-optimal policies are attainable and significantly outperform heuristic policies.
ISSN:0269-9648
1469-8951
DOI:10.1017/S026996481700016X