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Optimal and Near-Optimal (s,S) Inventory Policies for Levy Demand Processes

Published online by Cambridge University Press:  15 August 2002

Robin O. Roundy
Affiliation:
School of Operations Research and Industrial Engineering, Cornell University, Ithaca, NY 14853, U.S.A.
Gennady Samorodnitsky
Affiliation:
School of Operations Research and Industrial Engineering, Cornell University, Ithaca, NY 14853, U.S.A.
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Abstract

A Levy jump process is a continuous-time, real-valued stochasticprocess which has independent and stationary increments, with no Browniancomponent. We study some of the fundamental properties of Levy jumpprocesses and develop (s,S) inventory models for them. Of particularinterest to us is the gamma-distributed Levy process, in which the demandthat occurs in a fixed period of time has a gamma distribution.We study the relevant properties of these processes, and we develop aquadratically convergent algorithm for finding optimal (s,S) policies. Wedevelop a simpler heuristic policy and derive a bound on its relative cost. For the gamma-distributed Levy process this bound is 7.9% ifbackordering unfilled demand is at least twice as expensive as holdinginventory.Most easily-computed (s,S) inventory policies assume theinventory position to be uniform and assume that there is no overshoot. Ourtests indicate that these assumptions are dangerous when the coefficient ofvariation of the demand that occurs in the reorder interval is less than one. This is often the case for low-demand parts that experience sporadic orspiky demand. As long as the coefficient of variation of the demand thatoccurs in one reorder interval is at least one, and the service level isreasonably high, all of the polices we tested work very well. However evenin this region it is often the case that the standard Hadley–Whitin costfunction fails to have a local minimum.

Type
Research Article
Copyright
© EDP Sciences, 2001

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References

Asxater, S., Using the Deterministic EOQ Formula in Stochastic Inventory Control. Management Sci. 42 (1996) 830-834. CrossRef
Beyer, D. and Sethi, S., Average Cost Optimality in Inventory Models with Markovian Demands. J. Optim. Theory Appl. 92 (1997) 497-526. CrossRef
Bollapragada, S., A simple heuristic for computing nonstationary (s, S)policies. Oper. Res. 47 (1999) 576-585. CrossRef
Browne, S. and Zipkin, P., Inventory Models with Continuous, Stochastic Demands. Ann. Appl. Probab. 1 (1991) 419-435. CrossRef
Chen, F. and Zheng, Y., Inventory Policies with Quantized Ordering. Naval Res. Logist. 39 (1992) 654-665.
Cheung, K., Continuous Review Inventory Model, A with a Time Discount. IEEE Trans. 30 (1998) 747-757.
Federgruen, A. and Zheng, Y., Computing an Optimal (s,S) Policy is as Easy as Evaluating a Single Policy. Oper. Res. 39 (1991) 654-665.
Federgruen, A. and Zipkin, P., Computational Issues in an Infinite-Horizon, Multi-Echelon Inventory Model. Oper. Res. 32 (1984) 818-835. CrossRef
Federgruen, A. and Zipkin, P., Efficient Al, Angorithm for Computing Optimal (s,S) Policies. Oper. Res. 32 (1984) 1268-1285. CrossRef
Federgruen, A. and Zipkin, P., Computing Optimal (s,S) Policies in Inventory Models with Continuous Demands. Adv. in Appl. Probab. 17 (1985) 424-442.
W. Feller, An Introduction to Probability and its Applications, Vol. II. Wiley, New York (1966).
Sample Path Der, M. Fuivatives for (s,S) Inventory Systems. Oper. Res. 42 (1994) 351-364.
Hu, J., Nananukul, S. and Gong, W., New Approach, A to (s,S) Inventory Systems. J. Appl. Probab. 30 (1993) 898-912.
Gallego, G., New Bounds and Heuristics for (Q,r) Policies. Management Sci. 44 (1988) 219-233. CrossRef
G. Gallego and T. Boyaci, Managing Waiting Time Related Service Levels in Single-Stage (Q,r) Inventory Systems, Working paper. Department of Industrial Engineering and Operations Research, Columbia University, New York, NY (2000).
G. Gallego and T. Boyaci, Minimizing Holding and Ordering Costs subject to a Bound on Backorders is as Easy as Solving a Single Backorder Cost Model, Working paper. Department of Industrial Engineering and Operations Research, Columbia University, New York, NY (2000).
G. Gallego and T. Boyaci, Minimizing Average Ordering and Holding Costs subject to Service Constraints, Working paper. Department of Industrial Engineering and Operations Research, Columbia University, New York, NY (2000).
G.J. Hadley and T.M. Whitin, Analysis of Inventory Systems. Prentice Hall, Englewood Cliffs, NJ (1963).
T. Hida, Stationary Stochastic Processes. Princeton University Press, Princeton, NJ (1970).
L.A. Johnson and D.C. Montgomery, Operations Research in Production Planning, Scheduling, and Inventory Control. John Wiley and Sons, New York (1974).
S. Nahmias, Production and Operations Analysis, Second Edition. Irwin, Homewood Illinois, 60430 (1993).
N.U. Prabhu, Stochastic Storage Processes. Springer-Verlag, New York (1980).
S. Resnick, Adventures in Stochastic Processes. Birkhauser, Boston, MA (1992).
Robinson, L., Tractible (Q,R) Heuristic Models for Constrained Service Levels. Management Sci. 43 (1997) 951-965.
R. Roundy and G. Samorodnitsky, Optimal and Heuristic (s,S) Inventory Policies for Levy Demand Processes, Technical Report. School of Opeations Research and Industrial Engineering, Cornell University, Ithaca NY 14853 (1996).
Sahin, I., On the Objective Function Behavior in (s,S) Inventory Models. Oper. Res. 82 (1982) 709-724. CrossRef
Serfozo, R. and Stidham, S., Semi-Stationary Clearing Processes. Stochastic Process. Appl. 6 (1978) 165-178. CrossRef
M. Sharpe, General Theory of Markov Porcesses. Academic Press, Boston Massachusetts (1988).
Song, J. and Zipkin, P., Inventory Control in a Fluctuating Demand Environment. Oper. Res. 41 (1993) 351-370. CrossRef
T.E. Vollman, W.L. Berry and D.C. Whybark, Manufacturing Planning and Control Systems, Third Edition. Irwin, Homewood Illinois (1992).
Zheng, Y. and Federgruen, A., Finding Optimal (s,S) Policies is About as Simple as Evaluating a Single Policy. Oper. Res. 39 (1991) 654-665. CrossRef
Zheng, Y., Properties, On of Stochastic Inventory Systems. Management Sci. 38 (1992) 87-103. CrossRef
Zipkin, P., Stochastic Lead Times in Continuous-Time Inventory Models. Naval Res. Logist. Quarterly 33 (1986) 763-774. CrossRef
P. Zipkin, Foundations of Inventory Management. McGraw-Hill, Boston Massachusetts (2000).