English

Optimal spread for spanning subgraphs of Dirac hypergraphs

Combinatorics 2024-09-04 v2

Abstract

Let GG and HH be hypergraphs on nn vertices, and suppose HH has large enough minimum degree to necessarily contain a copy of GG as a subgraph. We give a general method to randomly embed GG into HH with good "spread". More precisely, for a wide class of GG, we find a randomised embedding f ⁣:GHf\colon G\hookrightarrow H with the following property: for every ss, for any partial embedding ff' of ss vertices of GG into HH, the probability that ff extends ff' is at most O(1/n)sO(1/n)^s. This is a common generalisation of several streams of research surrounding the classical Dirac-type problem. For example, setting s=ns=n, we obtain an asymptotically tight lower bound on the number of embeddings of GG into HH. This recovers and extends recent results of Glock, Gould, Joos, K\"uhn, and Osthus and of Montgomery and Pavez-Sign\'e regarding enumerating Hamilton cycles in Dirac hypergraphs. Moreover, using the recent developments surrounding the Kahn--Kalai conjecture, this result implies that many Dirac-type results hold robustly, meaning GG still embeds into HH after a random sparsification of its edge set. This allows us to recover a recent result of Kang, Kelly, K\"uhn, Osthus, and Pfenninger and of Pham, Sah, Sawhney, and Simkin for perfect matchings, and obtain novel results for Hamilton cycles and factors in Dirac hypergraphs. Notably, our randomised embedding algorithm is self-contained and does not require Szemer\'edi's regularity lemma or iterative absorption.

Keywords

Cite

@article{arxiv.2308.08535,
  title  = {Optimal spread for spanning subgraphs of Dirac hypergraphs},
  author = {Tom Kelly and Alp Müyesser and Alexey Pokrovskiy},
  journal= {arXiv preprint arXiv:2308.08535},
  year   = {2024}
}
R2 v1 2026-06-28T11:57:17.586Z