Optimal path and cycle decompositions of dense quasirandom graphs

Stefan Glock; Daniela Kühn; Deryk Osthus

doi:10.1016/j.endm.2015.06.011

Optimal path and cycle decompositions of dense quasirandom graphs

Stefan Glock, Daniela Kühn, Deryk Osthus

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

Abstract

Motivated by longstanding conjectures regarding decompositions of graphs into paths and cycles, we prove the following optimal decomposition results for random graphs. Let 0n,p. Let odd(G) be the number of odd degree vertices in G. Then a.a.s. the following hold:(i)G can be decomposed into δ(G)/2 cycles and a matching of size odd(G)/2.(ii)G can be decomposed into max {odd(G)/2, ⌈δ(G)/2⌉} paths.(iii)G can be decomposed into ⌈δ(G)/2⌉linear forests. Each of these bounds is best possible. We actually derive (i)-(iii) from 'quasi-random' versions of our results. In that context, we also determine the edge chromatic number of a given dense quasirandom graph of even order. For all these results, our main tool is a result on Hamilton decompositions of robust expanders by Kühn and Osthus.

Original language	English
Pages (from-to)	65-72
Number of pages	8
Journal	Electronic Notes in Discrete Mathematics
Volume	49
DOIs	https://doi.org/10.1016/j.endm.2015.06.011
Publication status	Published - 1 Nov 2015

Keywords

Cycle decomposition
Linear arboricity
Overfull subgraph conjecture
Path decomposition

ASJC Scopus subject areas

Discrete Mathematics and Combinatorics
Applied Mathematics

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title = "Optimal path and cycle decompositions of dense quasirandom graphs",

abstract = "Motivated by longstanding conjectures regarding decompositions of graphs into paths and cycles, we prove the following optimal decomposition results for random graphs. Let 0n,p. Let odd(G) be the number of odd degree vertices in G. Then a.a.s. the following hold:(i)G can be decomposed into δ(G)/2 cycles and a matching of size odd(G)/2.(ii)G can be decomposed into max {odd(G)/2, ⌈δ(G)/2⌉} paths.(iii)G can be decomposed into ⌈δ(G)/2⌉linear forests. Each of these bounds is best possible. We actually derive (i)-(iii) from 'quasi-random' versions of our results. In that context, we also determine the edge chromatic number of a given dense quasirandom graph of even order. For all these results, our main tool is a result on Hamilton decompositions of robust expanders by K{\"u}hn and Osthus.",

keywords = "Cycle decomposition, Linear arboricity, Overfull subgraph conjecture, Path decomposition",

author = "Stefan Glock and Daniela K{\"u}hn and Deryk Osthus",

year = "2015",

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doi = "10.1016/j.endm.2015.06.011",

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T1 - Optimal path and cycle decompositions of dense quasirandom graphs

AU - Glock, Stefan

AU - Kühn, Daniela

AU - Osthus, Deryk

PY - 2015/11/1

Y1 - 2015/11/1

N2 - Motivated by longstanding conjectures regarding decompositions of graphs into paths and cycles, we prove the following optimal decomposition results for random graphs. Let 0n,p. Let odd(G) be the number of odd degree vertices in G. Then a.a.s. the following hold:(i)G can be decomposed into δ(G)/2 cycles and a matching of size odd(G)/2.(ii)G can be decomposed into max {odd(G)/2, ⌈δ(G)/2⌉} paths.(iii)G can be decomposed into ⌈δ(G)/2⌉linear forests. Each of these bounds is best possible. We actually derive (i)-(iii) from 'quasi-random' versions of our results. In that context, we also determine the edge chromatic number of a given dense quasirandom graph of even order. For all these results, our main tool is a result on Hamilton decompositions of robust expanders by Kühn and Osthus.

AB - Motivated by longstanding conjectures regarding decompositions of graphs into paths and cycles, we prove the following optimal decomposition results for random graphs. Let 0n,p. Let odd(G) be the number of odd degree vertices in G. Then a.a.s. the following hold:(i)G can be decomposed into δ(G)/2 cycles and a matching of size odd(G)/2.(ii)G can be decomposed into max {odd(G)/2, ⌈δ(G)/2⌉} paths.(iii)G can be decomposed into ⌈δ(G)/2⌉linear forests. Each of these bounds is best possible. We actually derive (i)-(iii) from 'quasi-random' versions of our results. In that context, we also determine the edge chromatic number of a given dense quasirandom graph of even order. For all these results, our main tool is a result on Hamilton decompositions of robust expanders by Kühn and Osthus.

KW - Cycle decomposition

KW - Linear arboricity

KW - Overfull subgraph conjecture

KW - Path decomposition

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DO - 10.1016/j.endm.2015.06.011

M3 - Article

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SN - 1571-0653

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SP - 65

EP - 72

JO - Electronic Notes in Discrete Mathematics

JF - Electronic Notes in Discrete Mathematics

ER -

Optimal path and cycle decompositions of dense quasirandom graphs

Abstract

Keywords

ASJC Scopus subject areas

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