English

Improved Bounds for the Flat Wall Theorem

Data Structures and Algorithms 2014-10-02 v1 Discrete Mathematics

Abstract

The Flat Wall Theorem of Robertson and Seymour states that there is some function ff, such that for all integers w,t>1w,t>1, every graph GG containing a wall of size f(w,t)f(w,t), must contain either (i) a KtK_t-minor; or (ii) a small subset AV(G)A\subset V(G) of vertices, and a flat wall of size ww in GAG\setminus A. Kawarabayashi, Thomas and Wollan recently showed a self-contained proof of this theorem with the following two sets of parameters: (1) f(w,t)=Θ(t24(t2+w))f(w,t)=\Theta(t^{24}(t^2+w)) with A=O(t24)|A|=O(t^{24}), and (2) f(w,t)=w2Θ(t24)f(w,t)=w^{2^{\Theta(t^{24})}} with At5|A|\leq t-5. The latter result gives the best possible bound on A|A|. In this paper we improve their bounds to f(w,t)=Θ(t(t+w))f(w,t)=\Theta(t(t+w)) with At5|A|\leq t-5. For the special case where the maximum vertex degree in GG is bounded by DD, we show that, if GG contains a wall of size Ω(Dt(t+w))\Omega(Dt(t+w)), then either GG contains a KtK_t-minor, or there is a flat wall of size ww in GG. This setting naturally arises in algorithms for the Edge-Disjoint Paths problem, with D4D\leq 4. Like the proof of Kawarabayashi et al., our proof is self-contained, except for using a well-known theorem on routing pairs of disjoint paths. We also provide efficient algorithms that return either a model of the KtK_t-minor, or a vertex set AA and a flat wall of size ww in GAG\setminus A. We complement our result for the low-degree scenario by proving an almost matching lower bound: namely, for all integers w,t>1w,t>1, there is a graph GG, containing a wall of size Ω(wt)\Omega(wt), such that the maximum vertex degree in GG is 5, and GG contains no flat wall of size ww, and no KtK_t-minor.

Cite

@article{arxiv.1410.0276,
  title  = {Improved Bounds for the Flat Wall Theorem},
  author = {Julia Chuzhoy},
  journal= {arXiv preprint arXiv:1410.0276},
  year   = {2014}
}
R2 v1 2026-06-22T06:10:42.860Z