English

The largest subgraph without a forbidden induced subgraph

Combinatorics 2024-06-11 v2 Probability

Abstract

We initiate the systematic study of the following Tur\'an-type question. Suppose Γ\Gamma is a graph with nn vertices such that the edge density between any pair of subsets of vertices of size at least tt is at most 1c1 - c, for some tt and c>0c > 0. What is the largest number of edges in a subgraph GΓG \subseteq \Gamma which does not contain a fixed graph HH as an induced subgraph or, more generally, which belongs to a hereditary property P\mathcal{P}? This provides a common generalization of two recently studied cases, namely Γ\Gamma being a (pseudo-)random graph and a graph without a large complete bipartite subgraph. We focus on the interesting case where HH is a bipartite graph. We determine the answer up to a constant factor with respect to nn and tt, for certain bipartite HH and for Γ\Gamma either a dense random graph or a Paley graph with a square number of vertices. In particular, our bounds match if HH is a tree, or if one part of HH has dd vertices complete to the other part, all other vertices in that part have degree at most dd, and the other part has sufficiently many vertices. As applications of the latter result, we answer a question of Alon, Krivelevich, and Samotij on the largest subgraph with a hereditary property which misses a bipartite graph, and determine up to a constant factor the largest number of edges in a string subgraph of Γ\Gamma. The proofs are based on a variant of the dependent random choice and a novel approach for finding induced copies by inductively defining probability distributions supported on induced copies of smaller subgraphs.

Keywords

Cite

@article{arxiv.2405.05902,
  title  = {The largest subgraph without a forbidden induced subgraph},
  author = {Jacob Fox and Rajko Nenadov and Huy Tuan Pham},
  journal= {arXiv preprint arXiv:2405.05902},
  year   = {2024}
}

Comments

20 pages

R2 v1 2026-06-28T16:22:21.746Z