Nested Locally Hamiltonian Graphs and the Oberly-Sumner Conjecture

IF 0.5 4区数学 Q3 MATHEMATICS

Discussiones Mathematicae Graph Theory Pub Date : 2022-07-12 DOI:10.7151/dmgt.2346

Johan P. de Wet, M. Frick

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引用次数: 0

Abstract

Abstract A graph G is locally 𝒫, abbreviated L𝒫, if for every vertex v in G the open neighbourhood N(v) of v is non-empty and induces a graph with property 𝒫. Specifically, a graph G without isolated vertices is locally connected (LC) if N(v) induces a connected graph for each v ∈ V (G), and locally hamiltonian (LH) if N(v) induces a hamiltonian graph for each v ∈ V (G). A graph G is locally locally 𝒫 (abbreviated L2𝒫) if N(v) is non-empty and induces a locally 𝒫 graph for every v ∈ V (G). This concept is generalized to an arbitrary degree of nesting. For any k 0 we call a graph locally k-nested-hamiltonian if it is LmC for m = 0, 1, . . ., k and LkH (with L0C and L0H meaning connected and hamiltonian, respectively). The class of locally k-nested-hamiltonian graphs contains important subclasses. For example, Skupień had already observed in 1963 that the class of connected LH graphs (which is the class of locally 1-nested-hamiltonian graphs) contains all triangulations of closed surfaces. We show that for any k ≥ 1 the class of locally k-nested-hamiltonian graphs contains all simple-clique (k + 2)-trees. In 1979 Oberly and Sumner proved that every connected K1,3-free graph that is locally connected is hamiltonian. They conjectured that for k ≥ 1, every connected K1,k+3-free graph that is locally (k + 1)-connected is hamiltonian. We show that locally k-nested-hamiltonian graphs are locally (k + 1)-connected and consider the weaker conjecture that every K1,k+3-free graph that is locally k-nested-hamiltonian is hamiltonian. We show that if our conjecture is true, it would be “best possible” in the sense that for every k ≥ 1 there exist K1,k+4-free locally k-nested-hamiltonian graphs that are non-hamiltonian. We also attempt to determine the minimum order of non-hamiltonian locally k-nested-hamiltonian graphs and investigate the complexity of the Hamilton Cycle Problem for locally k-nested-hamiltonian graphs with restricted maximum degree.

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嵌套局部Hamilton图与Oberly-Sumner猜想

摘要图G是局部的，缩写为L，如果对于G上的每个顶点v, v的开邻域N(v)是非空的，则归纳出一个具有性质为p的图。具体来说，没有孤立顶点的图G是局部连通的(LC)，如果N(v)对每个v∈v (G)诱导出连通图，如果N(v)对每个v∈v (G)诱导出哈密顿图，则是局部连通的(LH)。如果N(v)非空，则图G是局部局部的(简称L2)，并且对每个v∈v (G)诱导出局部的(L2)图。这个概念被推广到任意程度的嵌套。对于任意k 0，我们称其为局部k嵌套哈密顿图，如果它是LmC，对于m = 0,1，…，k和LkH (L0C和L0H分别表示连通和哈密顿)。局部k嵌套哈密顿图类包含重要的子类。例如，skupieka在1963年就已经观察到连通LH图的类(即局部1嵌套哈密顿图的类)包含所有封闭曲面的三角剖分。我们证明了对于任意k≥1，局部k嵌套哈密顿图类包含所有的简单团(k + 2)树。1979年obely和Sumner证明了每一个局部连通的连通K1,3-自由图都是哈密顿图。他们推测，当k≥1时，每一个局部(k + 1)连通的连通K1,k+3自由图都是哈密顿的。我们证明了局部k嵌套哈密顿图是局部(k + 1)连通的，并考虑了一个较弱的猜想，即每一个K1,k+3自由的局部k嵌套哈密顿图都是哈密顿的。我们证明，如果我们的猜想是正确的，它将是“最佳可能”，因为对于每一个k≥1，存在K1,k+4自由的局部k嵌套哈密顿图是非哈密顿图。我们还尝试确定了非哈密顿局部k嵌套哈密顿图的最小阶，并研究了限制最大次的局部k嵌套哈密顿图的Hamilton循环问题的复杂性。

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

Discussiones Mathematicae Graph Theory MATHEMATICS-

CiteScore

2.20

自引率

0.00%

发文量

审稿时长

53 weeks

期刊介绍： The Discussiones Mathematicae Graph Theory publishes high-quality refereed original papers. Occasionally, very authoritative expository survey articles and notes of exceptional value can be published. The journal is mainly devoted to the following topics in Graph Theory: colourings, partitions (general colourings), hereditary properties, independence and domination, structures in graphs (sets, paths, cycles, etc.), local properties, products of graphs as well as graph algorithms related to these topics.