English

Treewidth Bounds for Planar Graphs Using Three-Sided Brambles

Combinatorics 2017-06-28 v1

Abstract

Square grids play a pivotal role in Robertson and Seymour's work on graph minors as planar obstructions to small treewidth. We introduce a three-sided bramble in a plane graph called a net, which generalizes the standard bramble of crosses in a square grid. We then characterize any minimal cover of a net as a tree drawn in the plane. We use nets in an O(n3)O(n^3) time algorithm that computes both upper and lower bounds on the bramble number (hence treewidth) of any planar graph. Let GG be a planar graph, BN(G)BN(G) be its bramble number and λ(G)\lambda(G) be the largest order of any net in a subgraph of GG. Our algorithm outputs a constant, KBKB, so that λ(G)/4KBBN(G)4KB4λ(G)\lambda(G)/4 \leq KB \leq BN(G)\leq 4KB \leq 4\lambda(G). Let s(G)s(G) be the size of a side of the largest square grid minor of GG. Smith (2015) has shown that λ(G)s(G)\lambda(G) \geq s(G). Our upper bound improves that of Grigoriev (2011) when λ(G)(5/4)s(G)\lambda(G)\leq (5/4)s(G). We correct a lower bound of Bodlaender, Grigoriev and Koster (2008) to s(G)/5s(G)/5 (instead of s(G)/4s(G)/4) and thus the lower bound of λ(G)/4\lambda(G)/4 on our approximation is an improvement.

Keywords

Cite

@article{arxiv.1706.08581,
  title  = {Treewidth Bounds for Planar Graphs Using Three-Sided Brambles},
  author = {Karen L. Collins and Brett C. Smith},
  journal= {arXiv preprint arXiv:1706.08581},
  year   = {2017}
}
R2 v1 2026-06-22T20:30:13.465Z