English

A Hall-type theorem with algorithmic consequences in planar graphs

Discrete Mathematics 2023-07-11 v2 Data Structures and Algorithms Combinatorics

Abstract

Given a graph G=(V,E)G=(V,E), for a vertex set SVS\subseteq V, let N(S)N(S) denote the set of vertices in VV that have a neighbor in SS. Extending the concept of binding number of graphs by Woodall~(1973), for a vertex set XVX \subseteq V, we define the binding number of XX, denoted by \bind(X)\bind(X), as the maximum number bb such that for every SXS \subseteq X where N(S)V(G)N(S)\neq V(G) it holds that N(S)bS|N(S)|\ge b {|S|}. Given this definition, we prove that if a graph V(G)V(G) contains a subset XX with \bind(X)=1/k\bind(X)= 1/k where kk is an integer, then GG possesses a matching of size at least X/(k+1)|X|/(k+1). Using this statement, we derive tight bounds for the estimators of the matching size in planar graphs. These estimators are previously used in designing sublinear space algorithms for approximating the maching size in the data stream model of computation. In particular, we show that the number of locally superior vertices is a 33 factor approximation of the matching size in planar graphs. The previous analysis by Jowhari (2023) proved a 3.53.5 approximation factor. As another application, we show a simple variant of an estimator by Esfandiari \etal (2015) achieves 33 factor approximation of the matching size in planar graphs. Namely, let ss be the number of edges with both endpoints having degree at most 22 and let hh be the number of vertices with degree at least 33. We prove that when the graph is planar, the size of matching is at least (s+h)/3(s+h)/3. This result generalizes a known fact that every planar graph on nn vertices with minimum degree 33 has a matching of size at least n/3n/3.

Keywords

Cite

@article{arxiv.2304.05859,
  title  = {A Hall-type theorem with algorithmic consequences in planar graphs},
  author = {Ebrahim Ghorbani and Hossein Jowhari},
  journal= {arXiv preprint arXiv:2304.05859},
  year   = {2023}
}

Comments

9 pages

R2 v1 2026-06-28T10:02:08.266Z