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DYNAMIC ANALYSIS OF A MULTIVARIATE REWARD PROCESS DEFINED ON THE UMCP WITH APPLICATION TO OPTIMAL PREVENTIVE MAINTENANCE POLICY PROBLEMS IN MANUFACTURING

Published online by Cambridge University Press:  28 March 2013

Jia-Ping Huang  and
Ushio Sumita
Jia-Ping Huang
Affiliation:
Department of Econometrics and OR, FEWEB, VU University Amsterdam, De Boelelaan 1105, 1081 HV Amsterdam, The Netherlands E-mail: j.huang@vu.nl
Ushio Sumita
Affiliation:
Division of Policy and Planning Sciences, Faculty of Engineering, Information and Systems, University of Tsukuba, 1-1-1 Tennoudai, Tsukuba, Ibaraki 305-8573, Japan E-mail: sumita@sk.tsukuba.ac.jp
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Abstract

The unified multivariate counting process (UMCP), previously studied by the same authors, enables one to describe most of the existing counting processes in terms of its components, thereby providing a comprehensive view for such processes often defined separately and differently. The purpose of this paper is to study a multivariate reward process defined on the UMCP. By examining the probabilistic flow in its state space, various transform results are obtained. The asymptotic behavior, as t→∞, of the expected univariate reward process in a form of a product of components of the multivariate reward process is studied. As an application, a manufacturing system is considered, where the cumulative profit given a preventive maintenance policy is described as a univariate reward process defined on the UMCP. The optimal preventive maintenance policy is derived numerically by maximizing the cumulative profit over the time interval [0, T].

Type
Research Article
Information
Probability in the Engineering and Informational Sciences , Volume 27 , Issue 2 , April 2013 , pp. 187 - 208
Copyright
Copyright © Cambridge University Press 2013

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References

1.Barlow, R. & Hunter, L. (1960). Optimum preventive maintenance policies. Operations Research 8: 90100.CrossRefGoogle Scholar
2.Çınlar, E. (1969). Markov renewal theory. Advances in Applied Probability 1: 123187.CrossRefGoogle Scholar
3.Çınlar, E. (1975). Markov renewal theory: a survey. Management Science 21: 727752.CrossRefGoogle Scholar
4.Feller, W. (1950). An introduction to probability theory and its applications, vol. 1. New York: Wiley.Google Scholar
5.Flehinger, B.J. (1962). A general model for the reliability analysis of systems under various preventive maintenance policies. The Annals of Mathematical Statistics 33: 137156.CrossRefGoogle Scholar
6.Heffes, H. & Lucantoni, D.M. (1986). A Markov modulated characterization of packetized voice and data traffic and related statistical multiplexer performance. IEEE Journal on Selected Areas in Communications 4: 856868.CrossRefGoogle Scholar
7.Jewell, W.S. (1963). Markov-renewal programming. i: formulation, finite return models. Operations Research 11: 938948.CrossRefGoogle Scholar
8.Keilson, J. (1966). A limit theorem for passage times in ergodic regenerative processes. The Annals of Mathematical Statistics 37: 866870.CrossRefGoogle Scholar
9.Keilson, J. (1969). On the matrix renewal function for markov renewal processes. The Annals of Mathematical Statistics 40: 19011907.CrossRefGoogle Scholar
10.Keilson, J. & Wishart, D.M.G. (1964). A central limit theorem for processes defined on a finite Markov. Proceedings of the Cambridge Philosophical Society 60: 547567.CrossRefGoogle Scholar
11.Keilson, J. & Wishart, D.M.G. (1965). Boundary problems for additive processes defined on a finite Markov chain (Homogeneous additive process defined on Markov chain with boundary states modification, noting Green function and passage time density). Proceedings of the Cambridge Philosophical Society 61: 173190.CrossRefGoogle Scholar
12.Lucantoni, D.M. (1991). New results on the single server queue with a batch Markovian arrival process. Stochastic Models 7: 146.CrossRefGoogle Scholar
13.Lucantoni, D.M., Meier-Hellstern, K.S. & Neuts, M.F. (1990). A single server queue with server vacations and a class of non-renewal arrival processes. Advances in Applied Probability 22: 676705.CrossRefGoogle Scholar
14.Malik, M.A.K. (1979). Reliable preventive maintenance scheduling. A I I E Transactions 11: 221228.CrossRefGoogle Scholar
15.Masuda, Y. (1993). Partially observable semi-markov reward processes. Journal of Applied Probability 30: 548560.CrossRefGoogle Scholar
16.Masuda, Y. & Sumita, U. (1987). Analysis of a counting process associated with a semi-Markov process: number of entries into a subset of state space. Advances in Applied Probability 19: 767783.CrossRefGoogle Scholar
17.Masuda, Y. & Sumita, U. (1991). A multivariate reward process defined on a semi-Markov process and its first-passage-time distributions. Journal of Applied Probability 28: 360373.CrossRefGoogle Scholar
18.McLean, R.A. & Neuts, M.F. (1967). The integral of a step function defined on a semi-Markov process. SIAM Journal on Applied Mathematics 15: 726737.CrossRefGoogle Scholar
19.Pierskalla, W.P. & Voelker, J.A. (1976). A survey of maintenance models: The control and surveillance of deteriorating systems. Naval Research Logistics Quarterly 23: 353388.CrossRefGoogle Scholar
20.Pyke, R. (1961a). Markov renewal processes: definitions and preliminary properties. The Annals of Mathematical Statistics 32: 12311242.CrossRefGoogle Scholar
21.Pyke, R. (1961b). Markov renewal processes with finitely many states. The Annals of Mathematical Statistics 32: 12431259.CrossRefGoogle Scholar
22.Pyke, R. & Schaufele, R. (1964). Limit theorems for Markov renewal processes. The Annals of Mathematical Statistics 35: 17461764.CrossRefGoogle Scholar
23.Ross, S.M. (1996). Stochastic processes. New York: Wiley, 2nd ed.Google Scholar
24.Smith, W.L. (1955). Regenerative stochastic processes. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences 232:613.Google Scholar
25.Stefanov, V.T. (2006). Exact distributions for reward functions on semi-Markov and Markov additive processes. Journal of Applied Probability 43: 10531065.CrossRefGoogle Scholar
26.Sumita, U. & Huang, J.-P. (2009). Dynamic analysis of a unified multivariate counting process and its asymptotic behavior. International Journal of Mathematics and Mathematical Sciences vol.2009: Article ID 219532, 43p. Doi:10.1155/2009/219532.CrossRefGoogle Scholar
27.Sumita, U. & Masuda, Y. (1987). An alternative approach to the analysis of finite semi-Markov and related processes. Stochastic Models 3: 6787.Google Scholar
28.Sumita, U. & Shanthikumar, J.G. (1988). An age-dependent counting process generated from a renewal process. Advances in Applied Probability 20: 739755.CrossRefGoogle Scholar
29.Valdez-Flores, C. & Feldman, R.M. (1989). A survey of preventive maintenance models for stochastically deteriorating single-unit systems. Naval Research Logistics 36: 419446.3.0.CO;2-5>CrossRefGoogle Scholar
30.Wang, H. (2002). A survey of maintenance policies of deteriorating systems. European Journal of Operational Research 139: 469489.CrossRefGoogle Scholar