English

Minors, connectivity, and diameter in randomly perturbed sparse graphs

Combinatorics 2022-12-15 v1

Abstract

Extremal properties of sparse graphs, randomly perturbed by the binomial random graph are considered. It is known that every nn-vertex graph GG contains a complete minor of order Ω(n/α(G))\Omega(n/\alpha(G)). We prove that adding ξn\xi n random edges, where ξ>0\xi > 0 is arbitrarily small yet fixed, to an nn-vertex graph GG satisfying α(G)ζ(ξ)n\alpha(G) \leq \zeta(\xi)n asymptotically almost surely results in a graph containing a complete minor of order Ω~(n/α(G))\tilde \Omega \left( n/\sqrt{\alpha(G)}\right); this result is tight up to the implicit logarithmic terms. For complete topological minors, we prove that there exists a constant C>0C>0 such that adding CnC n random edges to a graph GG satisfying δ(G)=ω(1)\delta(G) = \omega(1), asymptotically almost surely results in a graph containing a complete topological minor of order Ω~(min{δ(G),n})\tilde \Omega(\min\{\delta(G),\sqrt{n}\}); this result is tight up to the implicit logarithmic terms. Finally, extending results of Bohman, Frieze, Krivelevich, and Martin for the dense case, we analyse the asymptotic behaviour of the vertex-connectivity and the diameter of randomly perturbed sparse graphs.

Keywords

Cite

@article{arxiv.2212.07192,
  title  = {Minors, connectivity, and diameter in randomly perturbed sparse graphs},
  author = {Elad Aigner-Horev and Dan Hefetz and Michael Krivelevich},
  journal= {arXiv preprint arXiv:2212.07192},
  year   = {2022}
}
R2 v1 2026-06-28T07:34:19.408Z