$\theta$-free matching covered graphs
Abstract
A nontrivial connected graph is matching covered if each edge belongs to some perfect matching. For most problems pertaining to perfect matchings, one may restrict attention to matching covered graphs; thus, there is extensive literature on them. A cornerstone of this theory is an ear decomposition result due to Lov\'asz and Plummer. Their theorem is a fundamental problem-solving tool, and also yields interesting open problems; we discuss two such problems below, and we solve one of them. A subgraph of a graph is conformal if has a perfect matching. This notion is intrinsically related to the aforementioned ear decomposition theorem -- which implies that each matching covered graph (apart from and even cycles) contains a conformal bisubdivision of , or a conformal bisubdivision of , possibly both. (Here, refers to the graph with two vertices joined by three edges.) This immediately leads to two problems: characterize -free (likewise, -free) matching covered graphs. A characterization of planar -free matching covered graphs was obtained by Kothari and Murty [J. Graph Theory, 82 (1), 2016]; the nonplanar case is open. We provide a characterization of -free matching covered graphs that immediately implies a poly-time algorithm for the corresponding decision problem. Our characterization relies heavily on a seminal result due to Edmonds, Lov\'asz and Pulleyblank [Combinatorica, 2, 1982] pertaining to the tight cut decomposition theory of matching covered graphs. As corollaries, we provide two upper bounds on the size of a -free graph, namely, and , where denotes the number of bricks obtained in any tight cut decomposition of the graph; for each bound, we provide a characterization of the tight examples. The Petersen graph and play key roles in our results.
Cite
@article{arxiv.2407.05264,
title = {$\theta$-free matching covered graphs},
author = {Rohinee Joshi and Santhosh Raghul and Nishad Kothari},
journal= {arXiv preprint arXiv:2407.05264},
year = {2025}
}
Comments
We are working on a new version with more results. We intend to submit to a journal by end of 2025