A Threshold Inventory Rationing Policy for Service-Differentiated Demand Classes

Deshpande, Vinayak; Cohen, Morris A.; Donohue, Karen

doi:10.1287/mnsc.49.6.683.16022

Cited by 230 publications

(245 citation statements)

References 32 publications

(34 reference statements)

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“…Finally, there is a large body of literature on single-item inventory systems with multiple demand classes; see, for example, Deshpande et al (2003) and references therein. These systems can be viewed as special cases of an ATO system containing only a single common component but no product-specific components.…”

Section: Literature Reviewmentioning

confidence: 99%

No-Holdback Allocation Rules for Continuous-Time Assemble-to-Order Systems

Song

Zhao

2010

Operations Research

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This paper analyzes a class of common-component allocation rules, termed no-holdback (NHB) rules, in continuous-review assemble-to-order (ATO) systems with positive lead times. The inventory of each component is replenished following an independent base-stock policy. In contrast to the usually assumed first-come-first-served (FCFS) component allocation rule in the literature, an NHB rule allocates a component to a product demand only if it will yield immediate fulfillment of that demand. We identify metrics as well as cost and product structures under which NHB rules outperform all other component allocation rules. For systems with certain product structures, we obtain key performance expressions and compare them to those under FCFS. For general product structures, we present performance bounds and approximations. Finally, we discuss the applicability of these results to more general ATO systems.Subject classifications: stochastic multi-item inventory system; assemble-to-order; base-stock policy; common-component allocation rule; non-FCFS; sample-path analysis.

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Section: Literature Reviewmentioning

confidence: 99%

No-Holdback Allocation Rules for Continuous-Time Assemble-to-Order Systems

Song

Zhao

2010

Operations Research

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“…Moon and Kang (1998) later extend this model to account for compound Poisson demand processes. Deshpande et al (2003) analyze the same ( , ) Q R inventory rationing model with two demand classes as in Nahmias and Demmy (1981), but without the restriction on the number of outstanding orders. They introduce the threshold clearing mechanism to fill backorders, which permits them to derive expressions for the expected number of backorders for both classes without restrictions on the number of orders outstanding.…”

Section: Continuous-review Lost Salesmentioning

confidence: 99%

“…Melchiors et al (2000) also analyze a ( , ) Q R inventory model with two demand classes. Unlike Nahmias and Demmy (1981) and Deshpande et al (2003), they consider a lost sales environment so that demands from the low priority class are rejected whenever inventory level drops to the critical level. Melchiors (2001) extend the model in Melchiors et al (2000) to multiple Poisson demand classes with stochastic replenishment lead-times.…”

Section: Continuous-review Lost Salesmentioning

confidence: 99%

“…Melchiors (2001) extend the model in Melchiors et al (2000) to multiple Poisson demand classes with stochastic replenishment lead-times. Moreover, he considers a non-stationary critical-level policy that provides a benchmark to evaluate the stationary critical-level policy employed by Nahmias and Demmy (1981), Melchiors et al (2000), and Deshpande et al (2003). Dekker et al (1998) study an inventory model with two demand classes and one-for-one replenishment policy.…”

Section: Continuous-review Lost Salesmentioning

confidence: 99%

“…Our work is most closely related to that of Nahmias and Demmy (1981) and Deshpande et al (2003). However, whereas their work considers two demand classes, we have no restriction on the number of demand classes.…”

Section: General Frameworkmentioning

confidence: 99%

See 2 more Smart Citations

A Single-Product Inventory Model for Multiple Demand Classes

2007

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We consider a single-product inventory system that serves multiple demand classes, which differ in their shortage costs or service level requirements. We assume a critical-level control policy, and show the equivalence between this inventory system and a serial inventory system. Based on this equivalence, we develop a model for cost evaluation and optimization, under the assumptions of Poisson demand, deterministic replenishment lead-time, and a continuous-review (Q, R) policy with rationing. We propose a computationally-efficient heuristic and develop a bound on its performance.We provide a numerical experiment to show the effectiveness of the heuristic and the value from a rationing policy. Finally, we describe how to extend the model to permit service times, and to embed within a multi-echelon setting.

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Emergency transshipment in decentralized dealer networks: When to send and accept transshipment requests

Zhao

Deshpande

Ryan

2006

Naval Research Logistics

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Abstract:While there has been significant previous literature on inventory transshipment, most research has focused on the dealers' demand filling decision (when to fill transshipment requests from other dealers), ignoring the requesting decision (when to send transshipment requests to other dealers). In this paper we develop optimal inventory transshipment policies that incorporate both types of decisions. We consider a decentralized system in which the dealers are independent of the manufacturer and of each other. We first study a network consisting of a very large number of dealers. We prove that the optimal inventory and transshipment decisions for an individual dealer are controlled by threshold rationing and requesting levels. Then, in order to study the impact of transshipment among independent dealers in a smaller dealer network, we consider a decentralized two-dealer network and use a game theoretic approach to characterize the equilibrium inventory strategies of the individual dealers. An extensive numerical study highlights the impact of the requesting decision on the dealers' equilibrium behavior in a decentralized setting.

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A Threshold Inventory Rationing Policy for Service-Differentiated Demand Classes

Cited by 230 publications

References 32 publications

No-Holdback Allocation Rules for Continuous-Time Assemble-to-Order Systems

No-Holdback Allocation Rules for Continuous-Time Assemble-to-Order Systems

A Single-Product Inventory Model for Multiple Demand Classes

Emergency transshipment in decentralized dealer networks: When to send and accept transshipment requests

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