Saved in:
Bibliographic Details
Main Authors: Luo, Junjie, Wang, Changjun
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.10929
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917007287386112
author Luo, Junjie
Wang, Changjun
author_facet Luo, Junjie
Wang, Changjun
contents We analyze an infinite-horizon deterministic joint replenishment model from a non-cooperative game-theoretical approach. In this model, a group of retailers can choose to jointly place an order, which incurs a major setup cost independent of the group, and a minor setup cost for each retailer. Additionally, each retailer is associated with a holding cost. Our objective is to design cost allocation rules that minimize the long-run average system cost while accounting for the fact that each retailer independently selects its replenishment interval to minimize its own cost. We introduce a class of cost allocation rules that distribute the major setup cost among the associated retailers in proportion to their predefined weights. For these rules, we establish a monotonicity property of agent better responses, which enables us to prove the existence of a payoff dominant pure Nash equilibrium that can also be computed efficiently. We then analyze the efficiency of these equilibria by examining the price of stability (PoS), the ratio of the best Nash equilibrium's system cost to the social optimum, across different information settings. In particular, our analysis reveals that one rule, which leverages retailers' own holding cost rates, achieves a near-optimal PoS of 1.25, while another rule that does not require access to retailers' private information also yields a favorable PoS.
format Preprint
id arxiv_https___arxiv_org_abs_2510_10929
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Achieving Coordination in Non-Cooperative Joint Replenishment Games
Luo, Junjie
Wang, Changjun
Computer Science and Game Theory
We analyze an infinite-horizon deterministic joint replenishment model from a non-cooperative game-theoretical approach. In this model, a group of retailers can choose to jointly place an order, which incurs a major setup cost independent of the group, and a minor setup cost for each retailer. Additionally, each retailer is associated with a holding cost. Our objective is to design cost allocation rules that minimize the long-run average system cost while accounting for the fact that each retailer independently selects its replenishment interval to minimize its own cost. We introduce a class of cost allocation rules that distribute the major setup cost among the associated retailers in proportion to their predefined weights. For these rules, we establish a monotonicity property of agent better responses, which enables us to prove the existence of a payoff dominant pure Nash equilibrium that can also be computed efficiently. We then analyze the efficiency of these equilibria by examining the price of stability (PoS), the ratio of the best Nash equilibrium's system cost to the social optimum, across different information settings. In particular, our analysis reveals that one rule, which leverages retailers' own holding cost rates, achieves a near-optimal PoS of 1.25, while another rule that does not require access to retailers' private information also yields a favorable PoS.
title Achieving Coordination in Non-Cooperative Joint Replenishment Games
topic Computer Science and Game Theory
url https://arxiv.org/abs/2510.10929