Dichotomies for Maximum Matching Cut: H-Freeness, Bounded Diameter, Bounded Radius

International Symposium on Mathematical Foundations of Computer Science Pub Date : 2023-04-03 DOI:10.48550/arXiv.2304.01099

Felicia Lucke, D. Paulusma, B. Ries

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引用次数: 2

Abstract

The (Perfect) Matching Cut problem is to decide if a graph $G$ has a (perfect) matching cut, i.e., a (perfect) matching that is also an edge cut of $G$. Both Matching Cut and Perfect Matching Cut are known to be NP-complete, leading to many complexity results for both problems on special graph classes. A perfect matching cut is also a matching cut with maximum number of edges. To increase our understanding of the relationship between the two problems, we introduce the Maximum Matching Cut problem. This problem is to determine a largest matching cut in a graph. We generalize and unify known polynomial-time algorithms for Matching Cut and Perfect Matching Cut restricted to graphs of diameter at most $2$ and to $(P_6 + sP_2)$-free graphs. We also show that the complexity of Maximum Matching Cut} differs from the complexities of Matching Cut and Perfect Matching Cut by proving NP-hardness of Maximum Matching Cut for $2P_3$-free quadrangulated graphs of diameter 3 and radius 2 and for subcubic line graphs of triangle-free graphs. In this way, we obtain full dichotomies of Maximum Matching Cut for graphs of bounded diameter, bounded radius and $H$-free graphs.

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最大匹配切割的二分类:h自由度，有界直径，有界半径

(完美)匹配切问题是决定一个图$G$是否有一个(完美)匹配切，即，一个(完美)匹配也是$G$的边切。匹配切和完美匹配切都是已知的np完全的，这使得这两个问题在特殊的图类上得到了许多复杂的结果。完美匹配切割也是具有最大边数的匹配切割。为了加深我们对这两个问题之间关系的理解，我们引入了最大匹配割问题。这个问题是确定图中的最大匹配切割。我们推广并统一了已知的多项式时间算法，适用于直径不超过$2$的图和$(P_6 + sP_2)$自由图的匹配切和完美匹配切。通过证明直径为3、半径为2的$ 2p3 $自由四边形图和无三角形图的次立方线形图的最大匹配切的np -硬度，我们还证明了最大匹配切的复杂性不同于匹配切和完美匹配切的复杂性。通过这种方法，我们得到了有界直径图、有界半径图和$H$自由图的最大匹配切的完全二分类。

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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International Symposium on Mathematical Foundations of Computer Science

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