Maintaining a system subject to uncertain technological evolution

Maintenance decisions can be directly affected by the introduction of a new asset on the market, especially when the new asset technology could increase the expected profit. However new technology has a high degree of uncertainty that must be considered such as, e.g., its appearance time on the mark...

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Veröffentlicht in:	Reliability engineering & system safety 2014-08, Vol.128 (n128), p.56-65
Hauptverfasser:	Nguyen, T.P.K., Castanier, Bruno, Yeung, Thomas G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Computer Science Decision theory. Utility theory Decisions Dynamic programming Exact sciences and technology Financing Forecast horizon Horizon Investment Maintenance Maintenance/replacement investment Markets Markov decision processes Markov processes Mathematical models Mathematics Modeling and Simulation Operational research and scientific management Operational research. Management science Optimization Portfolio theory Probability and statistics Probability theory and stochastic processes Reliability theory. Replacement problems Sciences and techniques of general use Technology change
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container_title	Reliability engineering & system safety
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creator	Nguyen, T.P.K. Castanier, Bruno Yeung, Thomas G.
description	Maintenance decisions can be directly affected by the introduction of a new asset on the market, especially when the new asset technology could increase the expected profit. However new technology has a high degree of uncertainty that must be considered such as, e.g., its appearance time on the market, the expected revenue and the purchase cost. In this way, maintenance optimization can be seen as an investment problem where the repair decision is an option for postponing a replacement decision in order to wait for a potential new asset. Technology investment decisions are usually based primarily on strategic parameters such as current probability and expected future benefits while maintenance decisions are based on “functional” parameters such as deterioration levels of the current system and associated maintenance costs. In this paper, we formulate a new combined mathematical optimization framework for taking into account both maintenance and replacement decisions when the new asset is subject to technological improvement. The decision problem is modelled as a non-stationary Markov decision process. Structural properties of the optimal policy and forecast horizon length are then derived in order to guarantee decision optimality and robustness over the infinite horizon. Finally, the performance of our model is highlighted through numerical examples.
doi_str_mv	10.1016/j.ress.2014.04.004
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However new technology has a high degree of uncertainty that must be considered such as, e.g., its appearance time on the market, the expected revenue and the purchase cost. In this way, maintenance optimization can be seen as an investment problem where the repair decision is an option for postponing a replacement decision in order to wait for a potential new asset. Technology investment decisions are usually based primarily on strategic parameters such as current probability and expected future benefits while maintenance decisions are based on “functional” parameters such as deterioration levels of the current system and associated maintenance costs. In this paper, we formulate a new combined mathematical optimization framework for taking into account both maintenance and replacement decisions when the new asset is subject to technological improvement. The decision problem is modelled as a non-stationary Markov decision process. 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subjects	Applied sciences Computer Science Decision theory. Utility theory Decisions Dynamic programming Exact sciences and technology Financing Forecast horizon Horizon Investment Maintenance Maintenance/replacement investment Markets Markov decision processes Markov processes Mathematical models Mathematics Modeling and Simulation Operational research and scientific management Operational research. Management science Optimization Portfolio theory Probability and statistics Probability theory and stochastic processes Reliability theory. Replacement problems Sciences and techniques of general use Technology change
title	Maintaining a system subject to uncertain technological evolution
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