A generalization of Smith's theorem

M. Chrobak; S. Poljak

Displaying similar documents to “A generalization of Smith's theorem”

A note on pm-compact bipartite graphs

Jinfeng Liu, Xiumei Wang (2014)

Discussiones Mathematicae Graph Theory

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A graph is called perfect matching compact (briefly, PM-compact), if its perfect matching graph is complete. Matching-covered PM-compact bipartite graphs have been characterized. In this paper, we show that any PM-compact bipartite graph G with δ (G) ≥ 2 has an ear decomposition such that each graph in the decomposition sequence is also PM-compact, which implies that G is matching-covered

Conditions for β-perfectness

Judith Keijsper, Meike Tewes (2002)

Discussiones Mathematicae Graph Theory

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A β-perfect graph is a simple graph G such that χ(G') = β(G') for every induced subgraph G' of G, where χ(G') is the chromatic number of G', and β(G') is defined as the maximum over all induced subgraphs H of G' of the minimum vertex degree in H plus 1 (i.e., δ(H)+1). The vertices of a β-perfect graph G can be coloured with χ(G) colours in polynomial time (greedily). The main purpose of this paper is to give necessary and sufficient conditions, in terms of forbidden...

A Property Of The Number Of Perfect Matchings Of A Graph

Ivan Gutman (1991)

Publications de l'Institut Mathématique

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Perfect codes in regular graphs

I. Dvořáková-Rulićová (1988)

Commentationes Mathematicae Universitatis Carolinae

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A Maximum Resonant Set of Polyomino Graphs

Heping Zhang, Xiangqian Zhou (2016)

Discussiones Mathematicae Graph Theory

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A polyomino graph P is a connected finite subgraph of the infinite plane grid such that each finite face is surrounded by a regular square of side length one and each edge belongs to at least one square. A dimer covering of P corresponds to a perfect matching. Different dimer coverings can interact via an alternating cycle (or square) with respect to them. A set of disjoint squares of P is a resonant set if P has a perfect matching M so that each one of those squares is M-alternating....

Perfect matchings in $ε$ -regular graphs.

Alon, Noga, Rödl, Vojtěch, Ruciński, Andrzej (1998)

The Electronic Journal of Combinatorics [electronic only]

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A Simple Proof of the Perfect Matching Theorem

Ján Plesník (1975)

Matematický časopis

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Algorithmic aspects of bipartite graphs.

Bakonyi, Mihály, Varness, Erik M. (1995)

International Journal of Mathematics and Mathematical Sciences

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On maps: Continuous, closed, perfect, and with closed graph.

Garg, G.L., Goel, Asha (1997)

International Journal of Mathematics and Mathematical Sciences

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Polynomial time algorithms for two classes of subgraph problem

Sriraman Sridharan (2008)

RAIRO - Operations Research

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We design a polynomial time algorithm for finding a -1)- regular subgraph in a -regular graph without any induced star (claw-free). A polynomial time algorithm for finding a cubic subgraph in a 4-regular locally connected graph is also given. A family of -regular graphs with an induced star (, not containing any (-1)-regular subgraph is also constructed.

Pfaffian orientation and enumeration of perfect matchings for some Cartesian products of graphs.

Lin, Feng-Gen, Zhang, Lian-Zhu (2009)

The Electronic Journal of Combinatorics [electronic only]

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