A tight $$(1.5+\epsilon )$$ -approximation for unsplittable capacitated vehicle routing on trees

IF 2.2 2区数学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING Mathematical Programming Pub Date : 2024-05-25 DOI:10.1007/s10107-024-02094-z

Claire Mathieu, Hang Zhou

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Abstract

In the unsplittable capacitated vehicle routing problem (UCVRP) on trees, we are given a rooted tree with edge weights and a subset of vertices of the tree called terminals. Each terminal is associated with a positive demand between 0 and 1. The goal is to find a minimum length collection of tours starting and ending at the root of the tree such that the demand of each terminal is covered by a single tour (i.e., the demand cannot be split), and the total demand of the terminals in each tour does not exceed the capacity of 1.

For the special case when all terminals have equal demands, a long line of research culminated in a quasi-polynomial time approximation scheme [Jayaprakash and Salavatipour, TALG 2023] and a polynomial time approximation scheme [Mathieu and Zhou, TALG 2023].

In this work, we study the general case when the terminals have arbitrary demands. Our main contribution is a polynomial time $(1.5+\epsilon )$-approximation algorithm for the UCVRP on trees. This is the first improvement upon the 2-approximation algorithm more than 30 years ago. Our approximation ratio is essentially best possible, since it is NP-hard to approximate the UCVRP on trees to better than a 1.5 factor.

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树上不可分容车辆路由的$$(1.5+epsilon )$$ 精确近似值

在树上的不可拆分容车路由问题（UCVRP）中，我们给定了一棵带边权重的有根树和一个称为终点站的树顶子集。目标是找到一个起点和终点均为树根的最小长度巡回集合，使得每个终端的需求都能被一条巡回路线覆盖（即需求不能被拆分）、对于所有终端需求相等的特殊情况，经过长期研究，最终提出了准多项式时间近似方案 [Jayaprakash 和 Salavatipour, TALG 2023] 和多项式时间近似方案 [Mathieu 和 Zhou, TALG 2023]。我们的主要贡献是树上 UCVRP 的多项式时间（(1.5+\epsilon )\）逼近算法。这是对 30 多年前的 2-approximation 算法的首次改进。我们的逼近率基本上是最好的，因为要把树上的 UCVRP 逼近到优于 1.5 倍是 NP 难的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mathematical Programming 数学-计算机：软件工程

CiteScore

5.70

自引率

11.10%

发文量

160

审稿时长

4-8 weeks

期刊介绍： Mathematical Programming publishes original articles dealing with every aspect of mathematical optimization; that is, everything of direct or indirect use concerning the problem of optimizing a function of many variables, often subject to a set of constraints. This involves theoretical and computational issues as well as application studies. Included, along with the standard topics of linear, nonlinear, integer, conic, stochastic and combinatorial optimization, are techniques for formulating and applying mathematical programming models, convex, nonsmooth and variational analysis, the theory of polyhedra, variational inequalities, and control and game theory viewed from the perspective of mathematical programming.