A Multi-state Markov Model to Infer the Latent Deterioration Process From the Maintenance Effect on Reliability Engineering of Ships
Maintenance optimization of naval ship equipment is crucial in terms of national defense. However, the mixed effect of the maintenance and the pure deterioration processes in the observed data hinders an exact comparison between candidate maintenance policies. That is, the observed data-annual failu...
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Zusammenfassung: | Maintenance optimization of naval ship equipment is crucial in terms of
national defense. However, the mixed effect of the maintenance and the pure
deterioration processes in the observed data hinders an exact comparison
between candidate maintenance policies. That is, the observed data-annual
failure counts of naval ships reflect counteracting actions between the
maintenance and deterioration. The inference of the latent deteriorating
process is needed in advance for choosing an optimal maintenance policy to be
carried out. This study proposes a new framework for the separation of the true
deterioration effect by predicting it from the current maintenance effect
through the multi-state Markov model. Using an annual engine failure count of
99 ships in the Korean navy, we construct the framework consisting of
imputation, transition matrix design, optimization, and validation. The
hierarchical Gaussian process model is used for the imputation and the
three-state Markov model is applied for the estimation of parameters in the
deterioration and maintenance effect. To consider the natural (deterioration)
and artificial (maintenance) effect respectively, the Bayesian HMM model with a
categorical distribution is employed. Computational experiments under multiple
settings showed the robustness of the estimated parameters, as well as an
accurate recovery of the observed data, thereby confirming the credibility of
our model. The framework could further be employed to establish a reliable
maintenance system and to reduce an overall maintenance cost. |
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DOI: | 10.48550/arxiv.2111.14368 |