English

Hop-Spanners for Geometric Intersection Graphs

Computational Geometry 2024-11-04 v4 Combinatorics

Abstract

A tt-spanner of a graph G=(V,E)G=(V,E) is a subgraph H=(V,E)H=(V,E') that contains a uvuv-path of length at most tt for every uvEuv\in E. It is known that every nn-vertex graph admits a (2k1)(2k-1)-spanner with O(n1+1/k)O(n^{1+1/k}) edges for k1k\geq 1. This bound is the best possible for 1k91\leq k\leq 9 and is conjectured to be optimal due to Erd\H{o}s' girth conjecture. We study tt-spanners for t{2,3}t\in \{2,3\} for geometric intersection graphs in the plane. These spanners are also known as \emph{tt-hop spanners} to emphasize the use of graph-theoretic distances (as opposed to Euclidean distances between the geometric objects or their centers). We obtain the following results: (1) Every nn-vertex unit disk graph (UDG) admits a 2-hop spanner with O(n)O(n) edges; improving upon the previous bound of O(nlogn)O(n\log n). (2) The intersection graph of nn axis-aligned fat rectangles admits a 2-hop spanner with O(nlogn)O(n\log n) edges, and this bound is tight up to a factor of loglogn\log \log n. (3) The intersection graph of nn fat convex bodies in the plane admits a 3-hop spanner with O(nlogn)O(n\log n) edges. (4) The intersection graph of nn axis-aligned rectangles admits a 3-hop spanner with O(nlog2n)O(n\log^2 n) edges.

Keywords

Cite

@article{arxiv.2112.07158,
  title  = {Hop-Spanners for Geometric Intersection Graphs},
  author = {Jonathan B. Conroy and Csaba D. Tóth},
  journal= {arXiv preprint arXiv:2112.07158},
  year   = {2024}
}

Comments

36 pages, 24 figures, full version of an extended abstract in the Proceedings of SoCG 2022

R2 v1 2026-06-24T08:16:12.299Z