English

A spanning bandwidth theorem in random graphs

Combinatorics 2019-11-12 v1

Abstract

The bandwidth theorem [Mathematische Annalen, 343(1):175--205, 2009] states that any nn-vertex graph GG with minimum degree (k1k+o(1))n(\frac{k-1}{k}+o(1))n contains all nn-vertex kk-colourable graphs HH with bounded maximum degree and bandwidth o(n)o(n). In [arXiv:1612.00661] a random graph analogue of this statement is proved: for p(lognn)1/Δp\gg (\frac{\log n}{n})^{1/\Delta} a.a.s. each spanning subgraph GG of G(n,p)G(n,p) with minimum degree (k1k+o(1))pn(\frac{k-1}{k}+o(1))pn contains all nn-vertex kk-colourable graphs HH with maximum degree Δ\Delta, bandwidth o(n)o(n), and at least Cp2C p^{-2} vertices not contained in any triangle. This restriction on vertices in triangles is necessary, but limiting. In this paper we consider how it can be avoided. A special case of our main result is that, under the same conditions, if additionally all vertex neighbourhoods in GG contain many copies of KΔK_\Delta then we can drop the restriction on HH that Cp2Cp^{-2} vertices should not be in triangles.

Keywords

Cite

@article{arxiv.1911.03958,
  title  = {A spanning bandwidth theorem in random graphs},
  author = {Peter Allen and Julia Böttcher and Julia Ehrenmüller and Jakob Schnitzer and Anusch Taraz},
  journal= {arXiv preprint arXiv:1911.03958},
  year   = {2019}
}

Comments

26 pages. arXiv admin note: text overlap with arXiv:1612.00661

R2 v1 2026-06-23T12:10:48.469Z