Cycle lengths in randomly perturbed graphs

Elad Aigner-Horev; Dan Hefetz; Michael Krivelevich

doi:10.1002/rsa.21170

Cycle lengths in randomly perturbed graphs

Elad Aigner-Horev, Dan Hefetz, Michael Krivelevich

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

2 Scopus citations

Abstract

Let (Figure presented.) be an (Figure presented.) -vertex graph, where (Figure presented.) for some (Figure presented.). A result of Bohman, Frieze and Martin from 2003 asserts that if (Figure presented.), then perturbing (Figure presented.) via the addition of (Figure presented.) random edges, a.a.s. yields a Hamiltonian graph. We prove several improvements and extensions of the aforementioned result. In particular, keeping the bound on (Figure presented.) as above and allowing for (Figure presented.), we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a pancyclic graph. Moreover, we prove similar results for sparser graphs, and assuming the correctness of Chvátal's toughness conjecture, we handle graphs having larger independent sets. Finally, under milder conditions, we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a graph containing an almost spanning cycle.

Original language	English
Pages (from-to)	867-884
Number of pages	18
Journal	Random Structures and Algorithms
Volume	63
Issue number	4
DOIs	https://doi.org/10.1002/rsa.21170
State	Published - Dec 2023

Keywords

cycle lengths
hamiltonicity
independence number
pancyclicity
randomly perturbed graphs
toughness

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10.1002/rsa.21170

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title = "Cycle lengths in randomly perturbed graphs",

abstract = "Let (Figure presented.) be an (Figure presented.) -vertex graph, where (Figure presented.) for some (Figure presented.). A result of Bohman, Frieze and Martin from 2003 asserts that if (Figure presented.), then perturbing (Figure presented.) via the addition of (Figure presented.) random edges, a.a.s. yields a Hamiltonian graph. We prove several improvements and extensions of the aforementioned result. In particular, keeping the bound on (Figure presented.) as above and allowing for (Figure presented.), we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a pancyclic graph. Moreover, we prove similar results for sparser graphs, and assuming the correctness of Chv{\'a}tal's toughness conjecture, we handle graphs having larger independent sets. Finally, under milder conditions, we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a graph containing an almost spanning cycle.",

keywords = "cycle lengths, hamiltonicity, independence number, pancyclicity, randomly perturbed graphs, toughness",

author = "Elad Aigner-Horev and Dan Hefetz and Michael Krivelevich",

note = "Publisher Copyright: {\textcopyright} 2023 Wiley Periodicals LLC.",

year = "2023",

month = dec,

doi = "10.1002/rsa.21170",

language = "אנגלית",

volume = "63",

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T1 - Cycle lengths in randomly perturbed graphs

AU - Aigner-Horev, Elad

AU - Hefetz, Dan

AU - Krivelevich, Michael

PY - 2023/12

Y1 - 2023/12

N2 - Let (Figure presented.) be an (Figure presented.) -vertex graph, where (Figure presented.) for some (Figure presented.). A result of Bohman, Frieze and Martin from 2003 asserts that if (Figure presented.), then perturbing (Figure presented.) via the addition of (Figure presented.) random edges, a.a.s. yields a Hamiltonian graph. We prove several improvements and extensions of the aforementioned result. In particular, keeping the bound on (Figure presented.) as above and allowing for (Figure presented.), we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a pancyclic graph. Moreover, we prove similar results for sparser graphs, and assuming the correctness of Chvátal's toughness conjecture, we handle graphs having larger independent sets. Finally, under milder conditions, we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a graph containing an almost spanning cycle.

AB - Let (Figure presented.) be an (Figure presented.) -vertex graph, where (Figure presented.) for some (Figure presented.). A result of Bohman, Frieze and Martin from 2003 asserts that if (Figure presented.), then perturbing (Figure presented.) via the addition of (Figure presented.) random edges, a.a.s. yields a Hamiltonian graph. We prove several improvements and extensions of the aforementioned result. In particular, keeping the bound on (Figure presented.) as above and allowing for (Figure presented.), we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a pancyclic graph. Moreover, we prove similar results for sparser graphs, and assuming the correctness of Chvátal's toughness conjecture, we handle graphs having larger independent sets. Finally, under milder conditions, we determine the correct order of magnitude of the number of random edges whose addition to (Figure presented.) a.a.s. yields a graph containing an almost spanning cycle.

KW - cycle lengths

KW - hamiltonicity

KW - independence number

KW - pancyclicity

KW - randomly perturbed graphs

KW - toughness

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JO - Random Structures and Algorithms

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IS - 4

ER -

Cycle lengths in randomly perturbed graphs

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Keywords

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