English

Distinct degrees and homogeneous sets

Combinatorics 2022-12-01 v2

Abstract

In this paper we investigate the extremal relationship between two well-studied graph parameters: the order of the largest homogeneous set in a graph GG and the maximal number of distinct degrees appearing in an induced subgraph of GG, denoted respectively by hom(G)\hom (G) and f(G)f(G). Our main theorem improves estimates due to several earlier researchers and shows that if GG is an nn-vertex graph with hom(G)n1/2\hom (G) \geq n^{1/2} then f(G)(n/hom(G))1o(1)f(G) \geq \big ( {n}/{\hom (G)} \big )^{1 - o(1)}. The bound here is sharp up to the o(1)o(1)-term, and asymptotically solves a conjecture of Narayanan and Tomon. In particular, this implies that max{hom(G),f(G)}n1/2o(1)\max \{ \hom (G), f(G) \} \geq n^{1/2 -o(1)} for any nn-vertex graph GG,which is also sharp. The above relationship between hom(G)\hom (G) and f(G)f(G) breaks down in the regime where hom(G)<n1/2\hom (G) < n^{1/2}. Our second result provides a sharp bound for distinct degrees in biased random graphs, i.e. on f(G(n,p))f\big (G(n,p) \big ). We believe that the behaviour here determines the extremal relationship between hom(G)\hom (G) and f(G)f(G) in this second regime. Our approach to lower bounding f(G)f(G) proceeds via a translation into an (almost) equivalent probabilistic problem, and it can be shown to be effective for arbitrary graphs. It may be of independent interest.

Keywords

Cite

@article{arxiv.2204.05932,
  title  = {Distinct degrees and homogeneous sets},
  author = {Eoin Long and Laurentiu Ploscaru},
  journal= {arXiv preprint arXiv:2204.05932},
  year   = {2022}
}

Comments

35 pages, 2 figures, to appear in JCTB

R2 v1 2026-06-24T10:46:06.506Z