A Tight Lower Bound on Cubic Vertices and Upper Bounds on Thin and Non-thin edges in Planar Braces
Abstract
For a subset X of the vertex set () of a graph , we denote the set of edges of which have exactly one end in X by ∂(X) and refer to it as the cut of X or edge cut ∂(X). A graph =(,) is called matching covered if ∀ e ∈ (), ~∃ a perfect matching M of s. t. e ∈ M. A cut C of a matching covered graph is a separating cut if and only if, given any edge e, there is a perfect matching Me of such that e ∈ Me and |C Me| = 1. A cut C in a matching covered graph is a tight cut of if |C M| = 1 for every perfect matching M of . For, X, Y ⊂eq (), we denote the set of edges of () which have one endpoint in X and the other endpoint in Y by E[X,Y]. Let ∂(X)=E[X,X] be an edge cut, where X=() X. An edge cut is trivial if |X|=1 or |X|=1. A matching covered graph, which is free of nontrivial tight cuts, is a brace if it is bipartite and is a brick if it is non-bipartite. An edge e in a brace is thin if, for every tight cut ∂(X) of - e, |X| 3 or |X| 3. Carvalho, Lucchesi and Murty conjectured that there exists a positive constant c such that every brace has c|()| thin edges DBLP:journals/combinatorics/LucchesiCM15. He and Lu HE2025153 showed a lower bound of thin edges in a brace in terms of the number of cubic vertices. We asked whether any planar brace exists that does not contain any cubic vertices. We answer negatively by showing that such set of planar braces is empty. We have been able to show a quantitively tight lower bound on the number of cubic vertices in a planar brace. We have proved tight upper bounds of nonthin edges and thin edges in a planar brace.
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