English

Counting independent sets in hypergraphs

Combinatorics 2019-02-20 v2 Discrete Mathematics

Abstract

Let GG be a triangle-free graph with nn vertices and average degree tt. We show that GG contains at least e(1n1/12)12ntlnt(12lnt1) e^{(1-n^{-1/12})\frac{1}{2}\frac{n}{t}\ln t (\frac{1}{2}\ln t-1)} independent sets. This improves a recent result of the first and third authors \cite{countingind}. In particular, it implies that as nn \to \infty, every triangle-free graph on nn vertices has at least e(c1o(1))nlnne^{(c_1-o(1)) \sqrt{n} \ln n} independent sets, where c1=ln2/4=0.208138..c_1 = \sqrt{\ln 2}/4 = 0.208138... Further, we show that for all nn, there exists a triangle-free graph with nn vertices which has at most e(c2+o(1))nlnne^{(c_2+o(1))\sqrt{n}\ln n} independent sets, where c2=1+ln2=1.693147..c_2 = 1+\ln 2 = 1.693147... This disproves a conjecture from \cite{countingind}. Let HH be a (k+1)(k+1)-uniform linear hypergraph with nn vertices and average degree tt. We also show that there exists a constant ckc_k such that the number of independent sets in HH is at least ecknt1/kln1+1/kt. e^{c_{k} \frac{n}{t^{1/k}}\ln^{1+1/k}{t}}. This is tight apart from the constant ckc_k and generalizes a result of Duke, Lefmann, and R\"odl \cite{uncrowdedrodl}, which guarantees the existence of an independent set of size Ω(nt1/kln1/kt)\Omega(\frac{n}{t^{1/k}} \ln^{1/k}t). Both of our lower bounds follow from a more general statement, which applies to hereditary properties of hypergraphs.

Keywords

Cite

@article{arxiv.1310.6672,
  title  = {Counting independent sets in hypergraphs},
  author = {Jeff Cooper and Kunal Dutta and Dhruv Mubayi},
  journal= {arXiv preprint arXiv:1310.6672},
  year   = {2019}
}
R2 v1 2026-06-22T01:53:35.499Z