English

Large-Treewidth Graph Decompositions and Applications

Data Structures and Algorithms 2013-04-08 v1 Discrete Mathematics

Abstract

Treewidth is a graph parameter that plays a fundamental role in several structural and algorithmic results. We study the problem of decomposing a given graph GG into node-disjoint subgraphs, where each subgraph has sufficiently large treewidth. We prove two theorems on the tradeoff between the number of the desired subgraphs hh, and the desired lower bound rr on the treewidth of each subgraph. The theorems assert that, given a graph GG with treewidth kk, a decomposition with parameters h,rh,r is feasible whenever hr2k/\polylog(k)hr^2 \le k/\polylog(k), or h3rk/\polylog(k)h^3r \le k/\polylog(k) holds. We then show a framework for using these theorems to bypass the well-known Grid-Minor Theorem of Robertson and Seymour in some applications. In particular, this leads to substantially improved parameters in some Erdos-Posa-type results, and faster algorithms for a class of fixed-parameter tractable problems.

Keywords

Cite

@article{arxiv.1304.1577,
  title  = {Large-Treewidth Graph Decompositions and Applications},
  author = {Chandra Chekuri and Julia Chuzhoy},
  journal= {arXiv preprint arXiv:1304.1577},
  year   = {2013}
}

Comments

An extended abstract of the paper is to appear in Proceedings of ACM STOC, 2013

R2 v1 2026-06-21T23:54:18.491Z