English

Cycle lengths in randomly perturbed graphs

Combinatorics 2022-06-27 v1

Abstract

Let GG be an nn-vertex graph, where δ(G)δn\delta(G) \geq \delta n for some δ:=δ(n)\delta := \delta(n). A result of Bohman, Frieze and Martin from 2003 asserts that if α(G)=O(δ2n)\alpha(G) = O \left(\delta^2 n \right), then perturbing GG via the addition of ω(log(1/δ)δ3)\omega \left(\frac{\log(1/\delta)}{\delta^3} \right) random edges, asymptotically almost surely (a.a.s. hereafter) results in a Hamiltonian graph. This bound on the size of the random perturbation is only tight when δ\delta is independent of nn and deteriorates as to become uninformative when δ=Ω(n1/3)\delta = \Omega \left(n^{-1/3} \right). We prove several improvements and extensions of the aforementioned result. First, keeping the bound on α(G)\alpha(G) as above and allowing for δ=Ω(n1/3)\delta = \Omega(n^{-1/3}), we determine the correct order of magnitude of the number of random edges whose addition to GG a.a.s. results in a pancyclic graph. Our second result ventures into significantly sparser graphs GG; it delivers an almost tight bound on the size of the random perturbation required to ensure pancyclicity a.a.s., assuming δ(G)=Ω((α(G)logn)2)\delta(G) = \Omega \left((\alpha(G) \log n)^2 \right) and α(G)δ(G)=O(n)\alpha(G) \delta(G) = O(n). Assuming the correctness of Chv\'atal's toughness conjecture, allows for the mitigation of the condition α(G)=O(δ2n)\alpha(G) = O \left(\delta^2 n \right) imposed above, by requiring α(G)=O(δ(G))\alpha(G) = O(\delta(G)) instead; our third result determines, for a wide range of values of δ(G)\delta(G), the correct order of magnitude of the size of the random perturbation required to ensure the a.a.s. pancyclicity of GG. For the emergence of nearly spanning cycles, our fourth result determines, under milder conditions, the correct order of magnitude of the size of the random perturbation required to ensure that a.a.s. GG contains such a cycle.

Keywords

Cite

@article{arxiv.2206.12210,
  title  = {Cycle lengths in randomly perturbed graphs},
  author = {Elad Aigner-Horev and Dan Hefetz and Michael Krivelevich},
  journal= {arXiv preprint arXiv:2206.12210},
  year   = {2022}
}

Comments

21 pages, 4 figures

R2 v1 2026-06-24T12:02:55.973Z