Extensions of the Erdős–Gallai theorem and Luo’s theorem

Combinatorics, Probability and Computing Pub Date : 2019-10-08 DOI:10.1017/S0963548319000269

Bo Ning, Xing Peng

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引用次数: 30

Abstract

Abstract The famous Erdős–Gallai theorem on the Turán number of paths states that every graph with n vertices and m edges contains a path with at least (2m)/n edges. In this note, we first establish a simple but novel extension of the Erdős–Gallai theorem by proving that every graph G contains a path with at least $${{(s + 1){N_{s + 1}}(G)} \over {{N_s}(G)}} + s - 1$$ edges, where Nj(G) denotes the number of j-cliques in G for 1≤ j ≤ ω(G). We also construct a family of graphs which shows our extension improves the estimate given by the Erdős–Gallai theorem. Among applications, we show, for example, that the main results of [20], which are on the maximum possible number of s-cliques in an n-vertex graph without a path with ℓ vertices (and without cycles of length at least c), can be easily deduced from this extension. Indeed, to prove these results, Luo [20] generalized a classical theorem of Kopylov and established a tight upper bound on the number of s-cliques in an n-vertex 2-connected graph with circumference less than c. We prove a similar result for an n-vertex 2-connected graph with circumference less than c and large minimum degree. We conclude this paper with an application of our results to a problem from spectral extremal graph theory on consecutive lengths of cycles in graphs.

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Erdős-Gallai定理和罗定理的推广

著名的Turán条路径数Erdős-Gallai定理指出，每一个有n个顶点和m条边的图都包含一条至少有(2m)/n条边的路径。在这篇笔记中，我们首先通过证明每个图G包含至少有$${{(s + 1){N_{s + 1}}(G)} \over {{N_s}(G)}} + s - 1$$条边的路径来建立Erdős-Gallai定理的一个简单而新颖的扩展，其中Nj(G)表示当1≤j≤ω(G)时，G中j-团的个数。我们还构造了一组图，证明我们的推广改进了Erdős-Gallai定理给出的估计。例如，在应用中，我们证明了[20]的主要结果可以很容易地从这个扩展中推导出来，这些结果是关于在一个n顶点图中不存在具有r顶点的路径(并且不存在长度至少为c的循环)的s-团的最大可能数量。实际上，为了证明这些结果，Luo[20]推广了Kopylov的经典定理，并建立了周长小于c的n顶点2连通图中s-团数的紧上界。对于周长小于c且最小度较大的n顶点2连通图，我们证明了类似的结果。最后，我们将所得结果应用于图中关于连续循环长度的谱极值图论问题。

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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Combinatorics, Probability and Computing

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