Bounds on Half Graph Orders in Powers of Sparse Graphs

IF 0.7 4区数学 Q2 MATHEMATICS

Electronic Journal of Combinatorics Pub Date : 2023-04-07 DOI:10.37236/11063

Marek Sokołowski

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引用次数: 0

Abstract

Half graphs and their variants, such as semi-ladders and co-matchings, are configurations that encode total orders in graphs. Works by Adler and Adler (Eur. J. Comb.; 2014) and Fabiański et al. (STACS; 2019) prove that in powers of sparse graphs, one cannot find arbitrarily large configurations of this kind. However, these proofs either are non-constructive, or provide only loose upper bounds on the orders of half graphs and semi-ladders.In this work we provide nearly tight asymptotic lower and upper bounds on the maximum order of half graphs, parameterized by the power, in the following classes of sparse graphs: planar graphs, graphs with bounded maximum degree, graphs with bounded pathwidth or treewidth, and graphs excluding a fixed clique as a minor. The most significant part of our work is the upper bound for planar graphs. Here, we employ techniques of structural graph theory to analyze semi-ladders in planar graphs via the notion of cages, which expose a topological structure in semi-ladders. As an essential building block of this proof, we also state and prove a new structural result, yielding a fully polynomial bound on the neighborhood complexity in the class of planar graphs.

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稀疏图幂中半图阶的界

半图及其变体，如半阶梯和共匹配，是在图中编码总顺序的配置。阿德勒和阿德勒(欧洲)的作品。j .梳子。2014)和Fabiański等人(STACS;2019)证明了在稀疏图的幂次中，人们无法找到这种任意大的配置。然而，这些证明要么是非建设性的，要么只提供半图和半阶梯阶上的松散上界。在本文中，我们给出了用幂参数化的半图的最大阶的近紧渐近下界和上界，这些稀疏图包括:平面图、最大度有界的图、路径宽度或树宽度有界的图以及不包含固定团的图。我们的工作中最重要的部分是平面图的上界。在这里，我们采用结构图论的技术，通过笼的概念来分析平面图中的半阶梯，这暴露了半阶梯中的拓扑结构。作为这一证明的重要组成部分，我们还陈述并证明了一个新的结构结果，给出了平面图类的邻域复杂度的一个完全多项式界。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Electronic Journal of Combinatorics 数学-数学

CiteScore

1.30

自引率

14.30%

发文量

212

审稿时长

3-6 weeks

期刊介绍： The Electronic Journal of Combinatorics (E-JC) is a fully-refereed electronic journal with very high standards, publishing papers of substantial content and interest in all branches of discrete mathematics, including combinatorics, graph theory, and algorithms for combinatorial problems.