English

Sharp Threshold for Cliques in Random 0/1 Polytope Graphs

Combinatorics 2025-07-08 v1 Discrete Mathematics

Abstract

We study graph-theoretic properties of random 0/10/1 polytopes. Specifically, let Qpn{0,1}nQ_p^n \subseteq \{0,1\}^n be a random subset where each point is included independently with probability pp, and consider the graph GpG_p of the polytope conv(Qpn)(Q_p^n). We provide a short and combinatorial proof that p=2n/2p = 2^{-n/2} is a threshold for the edge density of GpG_p, a result originally due to Kaibel and Remshagen. We next resolve an open question from their paper by showing that for p2n/2o(1)p \leq 2^{-n/2 - o(1)}, GpG_p exhibits strong edge expansion. In particular, we prove that, with high probability, every vertex has degree (1o(1))Qpn(1 - o(1))|Q_p^n|. Lastly, we determine the threshold for GpG_p being a clique, strengthening a result of Bondarenko and Brodskiy. We show that with high probability, if p2δn+o(1)p \geq 2^{-\delta n + o(1)}, then GpG_p is not a clique, and if p2δno(1) p \leq 2^{-\delta n - o(1)}, then GpG_p is a clique, where δ0.8295\delta \approx 0.8295. Our approach combines a combinatorial characterization of edges in graphs arising from polytopes with the Kim-Vu polynomial concentration inequality.

Keywords

Cite

@article{arxiv.2507.03212,
  title  = {Sharp Threshold for Cliques in Random 0/1 Polytope Graphs},
  author = {Catherine Babecki and Tycho Elling and Asaf Ferber},
  journal= {arXiv preprint arXiv:2507.03212},
  year   = {2025}
}

Comments

18 pages, 2 figures

R2 v1 2026-07-01T03:46:04.964Z