English

Edge-statistics on large graphs

Combinatorics 2019-11-05 v2 Probability

Abstract

The inducibility of a graph HH measures the maximum number of induced copies of HH a large graph GG can have. Generalizing this notion, we study how many induced subgraphs of fixed order kk and size \ell a large graph GG on nn vertices can have. Clearly, this number is (nk)\binom{n}{k} for every nn, kk and {0,(k2)}\ell \in \left \{0, \binom{k}{2} \right\}. We conjecture that for every nn, kk and 0<<(k2)0 < \ell < \binom{k}{2} this number is at most (1/e+ok(1))(nk)\left(1/e + o_k(1) \right) \binom{n}{k}. If true, this would be tight for {1,k1}\ell \in \{1, k-1\}. In support of our `Edge-statistics conjecture' we prove that the corresponding density is bounded away from 11 by an absolute constant. Furthermore, for various ranges of the values of \ell we establish stronger bounds. In particular, we prove that for `almost all' pairs (k,)(k, \ell) only a polynomially small fraction of the kk-subsets of V(G)V(G) has exactly \ell edges, and prove an upper bound of (1/2+ok(1))(nk)(1/2 + o_k(1))\binom{n}{k} for =1\ell = 1. Our proof methods involve probabilistic tools, such as anti-concentration results relying on fourth moment estimates and Brun's sieve, as well as graph-theoretic and combinatorial arguments such as Zykov's symmetrization, Sperner's theorem and various counting techniques.

Keywords

Cite

@article{arxiv.1805.06848,
  title  = {Edge-statistics on large graphs},
  author = {Noga Alon and Dan Hefetz and Michael Krivelevich and Mykhaylo Tyomkyn},
  journal= {arXiv preprint arXiv:1805.06848},
  year   = {2019}
}

Comments

23 pages, revised version

R2 v1 2026-06-23T01:58:57.137Z