English

Bounding and computing obstacle numbers of graphs

Computational Geometry 2025-02-25 v3 Combinatorics

Abstract

An obstacle representation of a graph GG consists of a set of pairwise disjoint simply-connected closed regions and a one-to-one mapping of the vertices of GG to points such that two vertices are adjacent in GG if and only if the line segment connecting the two corresponding points does not intersect any obstacle. The obstacle number of a graph is the smallest number of obstacles in an obstacle representation of the graph in the plane such that all obstacles are simple polygons. It is known that the obstacle number of each nn-vertex graph is O(nlogn)O(n \log n) [Balko, Cibulka, and Valtr, 2018] and that there are nn-vertex graphs whose obstacle number is Ω(n/(loglogn)2)\Omega(n/(\log\log n)^2) [Dujmovi\'c and Morin, 2015]. We improve this lower bound to Ω(n/loglogn)\Omega(n/\log\log n) for simple polygons and to Ω(n)\Omega(n) for convex polygons. To obtain these stronger bounds, we improve known estimates on the number of nn-vertex graphs with bounded obstacle number, solving a conjecture by Dujmovi\'c and Morin. We also show that if the drawing of some nn-vertex graph is given as part of the input, then for some drawings Ω(n2)\Omega(n^2) obstacles are required to turn them into an obstacle representation of the graph. Our bounds are asymptotically tight in several instances. We complement these combinatorial bounds by two complexity results. First, we show that computing the obstacle number of a graph GG is fixed-parameter tractable in the vertex cover number of GG. Second, we show that, given a graph GG and a simple polygon PP, it is NP-hard to decide whether GG admits an obstacle representation using PP as the only obstacle.

Keywords

Cite

@article{arxiv.2206.15414,
  title  = {Bounding and computing obstacle numbers of graphs},
  author = {Martin Balko and Steven Chaplick and Robert Ganian and Siddharth Gupta and Michael Hoffmann and Pavel Valtr and Alexander Wolff},
  journal= {arXiv preprint arXiv:2206.15414},
  year   = {2025}
}
R2 v1 2026-06-24T12:10:01.578Z