English

The Bandwidth Theorem in Sparse Graphs

Combinatorics 2020-05-13 v2

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\big(\tfrac{k-1}{k}+o(1)\big)n contains all nn-vertex kk-colourable graphs HH with bounded maximum degree and bandwidth o(n)o(n). We provide sparse analogues of this statement in random graphs as well as pseudorandom graphs. More precisely, we show that for p(lognn)1/Δp\gg \big(\tfrac{\log n}{n}\big)^{1/\Delta} asymptotically almost surely each spanning subgraph GG of G(n,p)G(n,p) with minimum degree (k1k+o(1))pn\big(\tfrac{k-1}{k}+o(1)\big)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. A similar result is shown for sufficiently bijumbled graphs, which, to the best of our knowledge, is the first resilience result in pseudorandom graphs for a rich class of spanning subgraphs. Finally, we provide improved results for HH with small degeneracy, which in particular imply a resilience result in G(n,p)G(n,p) with respect to the containment of spanning bounded degree trees for p(lognn)1/3p\gg \big(\tfrac{\log n}{n}\big)^{1/3}.

Keywords

Cite

@article{arxiv.1612.00661,
  title  = {The Bandwidth Theorem in Sparse Graphs},
  author = {Peter Allen and Julia Böttcher and Julia Ehrenmüller and Anusch Taraz},
  journal= {arXiv preprint arXiv:1612.00661},
  year   = {2020}
}

Comments

60 pages

R2 v1 2026-06-22T17:11:40.538Z