Structural and computational results on platypus graphs

Jan Goedgebeur; Addie Neyt; Carol T. Zamfirescu

doi:10.1016/j.amc.2020.125491

Structural and computational results on platypus graphs

Jan Goedgebeur
, Addie Neyt
, Carol T. Zamfirescu

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

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 86 (2017) 223–243].

Original language	English
Article number	125491
Number of pages	10
Journal	Applied Mathematics and Computation
Volume	386
DOIs	https://doi.org/10.1016/j.amc.2020.125491
Publication status	Published - 1 Dec 2020
Externally published	Yes

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© 2020 Elsevier Inc.

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10.1016/j.amc.2020.125491

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title = "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 86 (2017) 223–243].",

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T1 - Structural and computational results on platypus graphs

AU - Goedgebeur, Jan

AU - Neyt, Addie

AU - Zamfirescu, Carol T.

PY - 2020/12/1

Y1 - 2020/12/1

N2 - 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 86 (2017) 223–243].

AB - 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 86 (2017) 223–243].

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DO - 10.1016/j.amc.2020.125491

M3 - Article

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VL - 386

JO - Applied Mathematics and Computation

JF - Applied Mathematics and Computation

M1 - 125491

ER -

Structural and computational results on platypus graphs

Abstract

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