Path Eccentricity and Forbidden Induced Subgraphs
Abstract
The path eccentricity of a connected graph G is the minimum integer k such that G has a path such that every vertex is at distance at most k from the path. A result of Duffus, Jacobson, and Gould from 1981 states that every connected \claw, net\-free graph G has a Hamiltonian path, that is, G has path eccentricity 0. Several more recent works identified various classes of connected graphs with path eccentricity at most 1, or, equivalently, graphs having a spanning caterpillar, including connected P5-free graphs, AT-free graphs, and biconvex graphs. Generalizing all these results, we apply the work on structural distance domination of Bacs\'o and Tuza [Discrete Math., 2012] and characterize, for every positive integer k, graphs such that every connected induced subgraph has path eccentricity less than k. More specifically, we show that every connected \Sk, Tk\-free graph has a path eccentricity less than k, where Sk and Tk are two specific graphs of path eccentricity k (a subdivided claw and the line graph of such a graph). As a consequence, every connected H-free graph has path eccentricity less than k if and only if H is an induced subgraph of 3Pk or P2k+1 + Pk-1. For such cases, we also provide a robust polynomial-time algorithm that finds a path witnessing the upper bound on the path eccentricity. Our main result also answers an open question of Bastide, Hilaire, and Robinson [Discrete Math., 2025].
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