English

Balanced Line Separators of Unit Disk Graphs

Computational Geometry 2019-08-20 v2 Discrete Mathematics Data Structures and Algorithms

Abstract

We prove a geometric version of the graph separator theorem for the unit disk intersection graph: for any set of nn unit disks in the plane there exists a line \ell such that \ell intersects at most O((m+n)logn)O(\sqrt{(m+n)\log{n}}) disks and each of the halfplanes determined by \ell contains at most 2n/32n/3 unit disks from the set, where mm is the number of intersecting pairs of disks. We also show that an axis-parallel line intersecting O(m+n)O(\sqrt{m+n}) disks exists, but each halfplane may contain up to 4n/54n/5 disks. We give an almost tight lower bound (up to sublogarithmic factors) for our approach, and also show that no line-separator of sublinear size in nn exists when we look at disks of arbitrary radii, even when m=0m=0. Proofs are constructive and suggest simple algorithms that run in linear time. Experimental evaluation has also been conducted, which shows that for random instances our method outperforms the method by Fox and Pach (whose separator has size O(m)O(\sqrt{m})).

Keywords

Cite

@article{arxiv.1709.02579,
  title  = {Balanced Line Separators of Unit Disk Graphs},
  author = {Paz Carmi and Man Kwun Chiu and Matthew J. Katz and Matias Korman and Yoshio Okamoto and André van Renssen and Marcel Roeloffzen and Taichi Shiitada and Shakhar Smorodinsky},
  journal= {arXiv preprint arXiv:1709.02579},
  year   = {2019}
}
R2 v1 2026-06-22T21:36:55.023Z