3,951 research outputs found
Computing Unique Maximum Matchings in O(m) time for Konig-Egervary Graphs and Unicyclic Graphs
Let alpha(G) denote the maximum size of an independent set of vertices and
mu(G) be the cardinality of a maximum matching in a graph G. A matching
saturating all the vertices is perfect. If alpha(G) + mu(G) equals the number
of vertices of G, then it is called a Konig-Egervary graph. A graph is
unicyclic if it has a unique cycle.
In 2010, Bartha conjectured that a unique perfect matching, if it exists, can
be found in O(m) time, where m is the number of edges.
In this paper we validate this conjecture for Konig-Egervary graphs and
unicylic graphs. We propose a variation of Karp-Sipser leaf-removal algorithm
(Karp and Spiser, 1981), which ends with an empty graph if and only if the
original graph is a Konig-Egervary graph with a unique perfect matching
obtained as an output as well.
We also show that a unicyclic non-bipartite graph G may have at most one
perfect matching, and this is the case where G is a Konig-Egervary graph.Comment: 10 pages, 5 figure
Local Maximum Stable Sets Greedoids Stemmed from Very Well-Covered Graphs
A maximum stable set in a graph G is a stable set of maximum cardinality. S
is called a local maximum stable set of G if S is a maximum stable set of the
subgraph induced by the closed neighborhood of S. A greedoid (V,F) is called a
local maximum stable set greedoid if there exists a graph G=(V,E) such that its
family of local maximum stable sets coinsides with (V,F). It has been shown
that the family local maximum stable sets of a forest T forms a greedoid on its
vertex set. In this paper we demonstrate that if G is a very well-covered
graph, then its family of local maximum stable sets is a greedoid if and only
if G has a unique perfect matching.Comment: 12 pages, 12 figure
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