Fast Fencing
Abstract
We consider very natural "fence enclosure" problems studied by Capoyleas, Rote, and Woeginger and Arkin, Khuller, and Mitchell in the early 90s. Given a set of points in the plane, we aim at finding a set of closed curves such that (1) each point is enclosed by a curve and (2) the total length of the curves is minimized. We consider two main variants. In the first variant, we pay a unit cost per curve in addition to the total length of the curves. An equivalent formulation of this version is that we have to enclose unit disks, paying only the total length of the enclosing curves. In the other variant, we are allowed to use at most closed curves and pay no cost per curve. For the variant with at most closed curves, we present an algorithm that is polynomial in both and . For the variant with unit cost per curve, or unit disks, we present a near-linear time algorithm. Capoyleas, Rote, and Woeginger solved the problem with at most curves in time. Arkin, Khuller, and Mitchell used this to solve the unit cost per curve version in exponential time. At the time, they conjectured that the problem with curves is NP-hard for general . Our polynomial time algorithm refutes this unless P equals NP.
Cite
@article{arxiv.1804.00101,
title = {Fast Fencing},
author = {Mikkel Abrahamsen and Anna Adamaszek and Karl Bringmann and Vincent Cohen-Addad and Mehran Mehr and Eva Rotenberg and Alan Roytman and Mikkel Thorup},
journal= {arXiv preprint arXiv:1804.00101},
year = {2018}
}