Bounded diameter tree-decompositions
Abstract
When does a graph admit a tree-decomposition in which every bag has small diameter? For finite graphs, this is a property of interest in algorithmic graph theory, where it is called having bounded ``tree-length''. We will show that this is equivalent to being ``boundedly quasi-isometric to a tree'', which for infinite graphs is a much-studied property from metric geometry. One object of this paper is to tie these two areas together. We will prove that there is a tree-decomposition in which each bag has small diameter, if and only if there is a map from into the vertex set of a tree , such that for all , the distances differ by at most a constant. A ``geodesic loaded cycle'' in is a pair , where is a cycle of and , such that for every pair of vertices of , one of the paths of between contains at most -edges, where is the distance between in . We will show that a graph admits a tree-decomposition in which every bag has small diameter, if and only if is small for every geodesic loaded cycle . Our proof is an extension of an algorithm to approximate tree-length in finite graphs by Dourisboure and Gavoille. In metric geometry, there is a similar theorem that characterizes when a graph is quasi-isometric to a tree, ``Manning's bottleneck criterion''. The goal of this paper is to tie all these concepts together, and add a few more related ideas. For instance, we prove a conjecture of Rose McCarty, that admits a tree-decomposition in which every bag has small diameter, if and only if for all vertices of , some ball of small radius meets every path joining two of .
Keywords
Cite
@article{arxiv.2306.13282,
title = {Bounded diameter tree-decompositions},
author = {Eli Berger and Paul Seymour},
journal= {arXiv preprint arXiv:2306.13282},
year = {2024}
}