Transversal factors and spanning trees

Q2 Mathematics Advances in Combinatorics Pub Date : 2021-07-09 DOI:10.19086/aic.2022.3

R. Montgomery, Alp Muyesser, Yanitsa Pehova

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引用次数: 16

Abstract

Since the proof of a "colorful" version of [Caratheodory's theorem](https://en.wikipedia.org/wiki/Carath%C3%A9odory%27s_theorem_%28convex_hull%29) by Bárány in 1982, it has been an important problem to obtain colorful extensions of other classical results in discrete geometry (for instance Tverberg's theorem). The present paper continues this line of research, but in the context of extremal graph theory rather than discrete geometry. Mantel's classical theorem from 1907 states that every $n$-vertex graph on more than $n^2/4$ edges contains a triangle. In [Ron Aharoni, Matt DeVos, Sebastián González Hermosillo de la Maza, Amanda Montejano, and Robert Šámal, A rainbow version of Mantel’s Theorem, Advances in Combinatorics 2020:2, 12 pp](https://arxiv.org/abs/1812.11872v2), a "rainbow", "colored", or "colorful" variant of this problem was considered : given three graphs $G_1,G_2,G_3$ on the same vertex set of size $n$, what average degree conditions on $G_1,G_2,G_3$ force the existence of a "rainbow triangle" (a triangle $\{e_1,e_2,e_3\}$ such that each edge $e_i$ belongs to $G_i$)? By taking three copies of the same graph $G$ we see that the colored version is at least as hard as the original problem, and the paper cited above provided a construction showing that in this case the colorful variant is strictly harder than Mantel's problem. It was suggested to study average degree or minimum degree thresholds for colorful variants of classical problems in extremal combinatorics, such as Dirac's theorem (every $n$-vertex graph of minimum degree at least $n/2$ has a Hamiltonian cycle). In particular, Joos and Kim proved in 2020 that the same minimum degree condition as in Dirac's theorem guarantees a rainbow $n$-cycle: namely if we are given $n$ graphs of minimum degree at least $n/2$ on the same set of $n$ vertices, then there is an $n$-cycle comprising one edge of each graph. The results in the present paper follow the same line of research. The two major results that are extended to the colorful setting here are a theorem of Kühn and Osthus (a sharp minimum degree condition to obtain a perfect packing of copies of any given graph $F$, generalizing the Hajnal-Szemerédi theorem), and a theorem of Komlós, Sárközy and Szemerédi (a sharp degree condition to contain any given spanning tree without large degree vertices). Amazingly, the minimum degree conditions in the (stronger) colorful versions are the same as the original minimum degree conditions.

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横向因子和生成树

自从1982年Bárány证明了[卡拉多里定理](https://en.wikipedia.org/wiki/Carath%C3%A9odory%27s_theorem_%28convex_hull%29)的“彩色”版本以来，在离散几何中获得其他经典结果的彩色扩展(例如特弗伯格定理)一直是一个重要的问题。本文继续这条研究路线，但在极值图论的背景下，而不是离散几何。曼特尔在1907年提出的经典定理指出，在超过n^2/4$条边上，每$n$顶点的图都包含一个三角形。在[Ron Aharoni, Matt DeVos, Sebastián González Hermosillo de la Maza, Amanda Montejano, and Robert Šámal，彩虹版的Mantel定理，Advances In Combinatorics 2020:2, 12 pp](https://arxiv.org/abs/1812.11872v2)中，考虑了这个问题的“彩虹”，“彩色”或“彩色”变体:给定三个图$G_1,G_2,G_3$在相同大小为$n$的顶点集上，$G_1,G_2,G_3$上的平均度数条件是什么迫使“彩虹三角形”(一个三角形$\{e_1,e_2,e_3\}$使得每条边$e_i$都属于$G_i$)的存在?通过取同一图$G$的三个副本，我们看到彩色版本至少和原始问题一样难，上面引用的论文提供了一个结构，表明在这种情况下，彩色版本严格地比Mantel的问题更难。建议研究极值组合中经典问题的彩色变体的平均度或最小度阈值，如狄拉克定理(至少$n/2$的最小度的$n$顶点图有一个哈密顿循环)。特别是，Joos和Kim在2020年证明了与Dirac定理中相同的最小度条件保证了彩虹$n$-环:即如果我们在相同的$n$顶点集上给定$n$最小度至少$n/2$的图，则存在包含每个图的一条边的$n$-环。本文的研究结果遵循了相同的研究思路。扩展到这里的两个主要结果是k hn和Osthus定理(获得任何给定图$F$副本的完美包合的锐最小度条件，推广hajnal - szemersamedi定理)，以及Komlós, Sárközy和szemersamedi定理(包含任何给定的无大度顶点的生成树的锐度条件)。令人惊讶的是，(较强)彩色版本中的最小度数条件与原始的最小度数条件相同。

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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