{"title":"Bounded-Diameter Tree-Decompositions","authors":"Eli Berger, Paul Seymour","doi":"10.1007/s00493-024-00088-1","DOIUrl":null,"url":null,"abstract":"<p>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 <span>\\(\\phi \\)</span> from <i>V</i>(<i>G</i>) into the vertex set of a tree <i>T</i>, such that for all <span>\\(u,v\\in V(G)\\)</span>, the distances <span>\\(d_G(u,v), d_T(\\phi (u),\\phi (v))\\)</span> differ by at most a constant. A necessary condition for admitting such a tree-decomposition is that there is no long geodesic cycle, and for graphs of bounded tree-width, Diestel and Müller showed that this is also sufficient. But it is not sufficient in general, even qualitatively, because there are graphs in which every geodesic cycle has length at most three, and yet every tree-decomposition has a bag with large diameter. There is a more general necessary condition, however. A “geodesic loaded cycle” in <i>G</i> is a pair (<i>C</i>, <i>F</i>), where <i>C</i> is a cycle of <i>G</i> and <span>\\(F\\subseteq E(C)\\)</span>, such that for every pair <i>u</i>, <i>v</i> of vertices of <i>C</i>, one of the paths of <i>C</i> between <i>u</i>, <i>v</i> contains at most <span>\\(d_G(u,v)\\)</span> <i>F</i>-edges, where <span>\\(d_G(u,v)\\)</span> is the distance between <i>u</i>, <i>v</i> in <i>G</i>. We will show that a (possibly infinite) graph <i>G</i> admits a tree-decomposition in which every bag has small diameter, if and only if |<i>F</i>| is small for every geodesic loaded cycle (<i>C</i>, <i>F</i>). 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 <i>G</i> admits a tree-decomposition in which every bag has small diameter, if and only if for all vertices <i>u</i>, <i>v</i>, <i>w</i> of <i>G</i>, some ball of small radius meets every path joining two of <i>u</i>, <i>v</i>, <i>w</i>.</p>","PeriodicalId":50666,"journal":{"name":"Combinatorica","volume":null,"pages":null},"PeriodicalIF":1.0000,"publicationDate":"2024-04-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Combinatorica","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1007/s00493-024-00088-1","RegionNum":2,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 0
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 \(\phi \) from V(G) into the vertex set of a tree T, such that for all \(u,v\in V(G)\), the distances \(d_G(u,v), d_T(\phi (u),\phi (v))\) differ by at most a constant. A necessary condition for admitting such a tree-decomposition is that there is no long geodesic cycle, and for graphs of bounded tree-width, Diestel and Müller showed that this is also sufficient. But it is not sufficient in general, even qualitatively, because there are graphs in which every geodesic cycle has length at most three, and yet every tree-decomposition has a bag with large diameter. There is a more general necessary condition, however. A “geodesic loaded cycle” in G is a pair (C, F), where C is a cycle of G and \(F\subseteq E(C)\), such that for every pair u, v of vertices of C, one of the paths of C between u, v contains at most \(d_G(u,v)\)F-edges, where \(d_G(u,v)\) is the distance between u, v in G. We will show that a (possibly infinite) graph G admits a tree-decomposition in which every bag has small diameter, if and only if |F| is small for every geodesic loaded cycle (C, F). 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 G admits a tree-decomposition in which every bag has small diameter, if and only if for all vertices u, v, w of G, some ball of small radius meets every path joining two of u, v, w.
期刊介绍:
COMBINATORICA publishes research papers in English in a variety of areas of combinatorics and the theory of computing, with particular emphasis on general techniques and unifying principles. Typical but not exclusive topics covered by COMBINATORICA are
- Combinatorial structures (graphs, hypergraphs, matroids, designs, permutation groups).
- Combinatorial optimization.
- Combinatorial aspects of geometry and number theory.
- Algorithms in combinatorics and related fields.
- Computational complexity theory.
- Randomization and explicit construction in combinatorics and algorithms.