关于分裂图的边着色和总着色的新结果

IF 1 3区 数学 Q3 MATHEMATICS, APPLIED
Fernanda Couto , Diego Amaro Ferraz , Sulamita Klein
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引用次数: 0

摘要

分裂图是指顶点集可以划分为一个群集和一个独立集的图。给定一个图 G,确定 G 是 t-admissible 的最小 t,即 G 的伸展指数(用 σ(G)表示),是 t-admissibility 问题的目标。分裂图是 3-admissible 的,可以划分为三个子类:σ=1、2 或 3 的分裂图。在这项工作中,我们在处理分裂图着色问题时考虑了这种划分。Vizing 证明,任何图的边都可以用 Δ 或 Δ+1 种颜色着色,因此可以分别归为第 1 类或第 2 类。当边和顶点同时着色时,可以推测任何图形都可以用 Δ+1 或 Δ+2 种颜色着色,因此可以分为第 1 类或第 2 类。对于分裂图,这两种变体都还没有定论。在本文中,我们利用上面介绍的分裂图分区,考虑了 σ=2 的分裂图的边着色问题和总着色问题。对于这一类图,我们描述了第 2 类图和第 2 类图的特征,并提供了对任何第 1 类图或第 1 类图着色的多项式时间算法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New results on edge-coloring and total-coloring of split graphs

A split graph is a graph whose vertex set can be partitioned into a clique and an independent set. A connected graph G is said to be t-admissible if admits a special spanning tree in which the distance between any two adjacent vertices is at most t. Given a graph G, determining the smallest t for which G is t-admissible, i.e., the stretch index of G, denoted by σ(G), is the goal of the t-admissibility problem. Split graphs are 3-admissible and can be partitioned into three subclasses: split graphs with σ=1,2 or 3. In this work we consider such a partition while dealing with the problem of coloring a split graph. Vizing proved that any graph can have its edges colored with Δ or Δ+1 colors, and thus can be classified as Class 1 or Class 2, respectively. When both, edges and vertices, are simultaneously colored, it is conjectured that any graph can be colored with Δ+1 or Δ+2 colors, and thus can be classified as Type 1 or Type 2. Both variants are still open for split graphs. In this paper, using the partition of split graphs presented above, we consider the edge coloring problem and the total coloring problem for split graphs with σ=2. For this class, we characterize Class 2 and Type 2 graphs and we provide polynomial-time algorithms to color any Class 1 or Type 1 graph.

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来源期刊
Discrete Applied Mathematics
Discrete Applied Mathematics 数学-应用数学
CiteScore
2.30
自引率
9.10%
发文量
422
审稿时长
4.5 months
期刊介绍: The aim of Discrete Applied Mathematics is to bring together research papers in different areas of algorithmic and applicable discrete mathematics as well as applications of combinatorial mathematics to informatics and various areas of science and technology. Contributions presented to the journal can be research papers, short notes, surveys, and possibly research problems. The "Communications" section will be devoted to the fastest possible publication of recent research results that are checked and recommended for publication by a member of the Editorial Board. The journal will also publish a limited number of book announcements as well as proceedings of conferences. These proceedings will be fully refereed and adhere to the normal standards of the journal. Potential authors are advised to view the journal and the open calls-for-papers of special issues before submitting their manuscripts. Only high-quality, original work that is within the scope of the journal or the targeted special issue will be considered.
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