Approximating the Nonlinear Newsvendor and Single-Item Stochastic Lot-Sizing Problems When Data Is Given by an Oracle

Author(s)

Halman, Nir; Simchi-Levi, David; Orlin, James B.

Abstract

The single-item stochastic lot-sizing problem is to find an inventory replenishment policy in the presence of discrete stochastic demands under periodic review and finite time horizon. A closely related problem is the single-period newsvendor model. It is well known that the newsvendor problem admits a closed formula for the optimal order quantity whenever the revenue and salvage values are linear increasing functions and the procurement (ordering) cost is fixed plus linear. The optimal policy for the single-item lot-sizing model is also well known under similar assumptions. In this paper we show that the classical (single-period) newsvendor model with fixed plus linear ordering cost cannot be approximated to any degree of accuracy when either the demand distribution or the cost functions are given by an oracle. We provide a fully polynomial time approximation scheme for the nonlinear single-item stochastic lot-sizing problem, when demand distribution is given by an oracle, procurement costs are provided as nondecreasing oracles, holding/backlogging/disposal costs are linear, and lead time is positive. Similar results exist for the nonlinear newsvendor problem. These approximation schemes are designed by extending the technique of K-approximation sets and functions.

Date issued

2012-03

URI

http://hdl.handle.net/1721.1/77227

Department

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering
Sloan School of Management

Journal

Operations Research

Publisher

Institute for Operations Research and the Management Sciences (INFORMS)

Citation

Halman, N., J. B. Orlin, and D. Simchi-Levi. “Approximating the Nonlinear Newsvendor and Single-Item Stochastic Lot-Sizing Problems When Data Is Given by an Oracle.” Operations Research 60.2 (2012): 429–446.

Version: Author's final manuscript

ISSN

0030-364X

1526-5463