用子图互补法切割一棵树是很难的，除非是一些小树

Pub Date : 2024-05-09 DOI:10.1002/jgt.23112

Dhanyamol Antony, Sagartanu Pal, R. B. Sandeep, R. Subashini

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引用次数: 0

摘要

对于一个图的属性而言，"补全子图"（Subgraph Complementation to）是一个问题，即找出输入图中是否存在这样一个顶点子集，即通过补全由其诱导的子图来进行修改，从而得到一个满足该属性的图。我们证明，对于树状图而言，子图补全到-free 图的问题是 NP-Complete（NP-Complete）的，但顶点数最多为 13 的 41 棵树（如果一个图不包含任何"-free "的诱导副本，则该图为-free）除外。这一结果，加上已知的四种多项式时间可解情况（当最多四个顶点上有一条路径时），留下了 37 种未解情况。此外，我们还证明，假设存在指数时间假说，这些难题不存在任何亚指数时间算法。作为附加结果，我们还得到了无爪图的子图补全可以在多项式时间内求解。

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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Cutting a tree with subgraph complementation is hard, except for some small trees

For a graph property $Π$ , Subgraph Complementation to $Π$ is the problem to find whether there is a subset $S$ of vertices of the input graph $G$ such that modifying $G$ by complementing the subgraph induced by $S$ results in a graph satisfying the property $Π$ . We prove that the problem of Subgraph Complementation to $T$ -free graphs is NP-Complete, for $T$ being a tree, except for 41 trees of at most 13 vertices (a graph is $T$ -free if it does not contain any induced copies of $T$ ). This result, along with the four known polynomial-time solvable cases (when $T$ is a path on at most four vertices), leaves behind 37 open cases. Further, we prove that these hard problems do not admit any subexponential-time algorithms, assuming the Exponential-Time Hypothesis. As an additional result, we obtain that Subgraph Complementation to paw-free graphs can be solved in polynomial-time.

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