Euclidean Capacitated Vehicle Routing in Random Setting: A $1.55$-Approximation Algorithm
Abstract
We study the unit-demand capacitated vehicle routing problem in the random setting of the Euclidean plane. The objective is to visit random terminals in a square using a set of tours of minimum total length, such that each tour visits the depot and at most terminals. We design an elegant algorithm combining the classical sweep heuristic and Arora's framework for the Euclidean traveling salesman problem [Journal of the ACM 1998]. We show that our algorithm is a polynomial-time approximation of ratio at most asymptotically almost surely. This improves on previous approximation ratios of due to Bompadre, Dror, and Orlin [Journal of Applied Probability 2007] and due to Mathieu and Zhou [Random Structures and Algorithms 2022]. In addition, we conjecture that, for any , our algorithm is a -approximation asymptotically almost surely.
Cite
@article{arxiv.2304.11281,
title = {Euclidean Capacitated Vehicle Routing in Random Setting: A $1.55$-Approximation Algorithm},
author = {Zipei Nie and Hang Zhou},
journal= {arXiv preprint arXiv:2304.11281},
year = {2023}
}
Comments
21 pages, 0 figures