Structural and computational results on platypus graphs
Abstract
A platypus graph is a non-hamiltonian graph for which every vertex-deleted subgraph is traceable. They are closely related to families of graphs satisfying interesting conditions regarding longest paths and longest cycles, for instance hypohamiltonian, leaf-stable, and maximally non-hamiltonian graphs. In this paper, we first investigate cubic platypus graphs, covering all orders for which such graphs exist: in the general and polyhedral case as well as for snarks. We then present (not necessarily cubic) platypus graphs of girth up to 16---whereas no hypohamiltonian graphs of girth greater than 7 are known---and study their maximum degree, generalising two theorems of Chartrand, Gould, and Kapoor. Using computational methods, we determine the complete list of all non-isomorphic platypus graphs for various orders and girths. Finally, we address two questions raised by the third author in [J. Graph Theory \textbf{86} (2017) 223--243].
Keywords
Cite
@article{arxiv.1712.05158,
title = {Structural and computational results on platypus graphs},
author = {Jan Goedgebeur and Addie Neyt and Carol T. Zamfirescu},
journal= {arXiv preprint arXiv:1712.05158},
year = {2017}
}
Comments
20 pages; submitted for publication