Hitting all longest paths in H-free graphs and H-graphs

Abstract

The longest path transversal number of a connected graph G, denoted by lpt(G), is the minimum size of a set of vertices of G that intersects all longest paths in G. We present constant upper bounds for the longest path transversal number of hereditary classes of graphs, that is, classes of graphs closed under taking induced subgraphs. Our first main result is a structural theorem that allows us to refine a given longest path transversal in a graph using domination properties. This has several consequences: First, it implies that for every t ∈ \5,6\, every connected Pt-free graph G satisfies lpt(G) ≤ t-2. Second, it shows that every (bull, chair)-free graph G satisfies lpt(G) ≤ 5. Third, it implies that for every t ∈ N, every connected chordal graph G with no induced subgraph isomorphic to Kt Kt satisfies lpt(G) ≤ t-1, where Kt Kt is the graph obtained from a t-clique and an independent set of size t by adding a perfect matching between them. Our second main result provides an upper bound for the longest path transversal number in H-intersection graphs. For a given graph H, a graph G is called an H-graph if there exists a subdivision H' of H such that G is the intersection graph of a family of vertex subsets of H' that each induce connected subgraphs. The concept of H-graphs, introduced by Bir\'o, Hujter, and Tuza, naturally captures interval graphs, circular-arc graphs, and chordal graphs, among others. Our result shows that for every connected graph H with at least two vertices, there exists an integer k = k(H) such that every connected H-graph G satisfies lpt(G) ≤ k.

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