English

What does a typical metric space look like?

Probability 2022-05-31 v2 Combinatorics Metric Geometry

Abstract

The collection Mn\mathcal{M}_n of all metric spaces on nn points whose diameter is at most 22 can naturally be viewed as a compact convex subset of R(n2)\mathbb{R}^{\binom{n}{2}}, known as the metric polytope. In this paper, we study the metric polytope for large nn and show that it is close to the cube [1,2](n2)Mn[1,2]^{\binom{n}{2}} \subseteq \mathcal{M}_n in the following two senses. First, the volume of the polytope is not much larger than that of the cube, with the following quantitative estimates: (16+o(1))n3/2logVol(Mn)O(n3/2). \left(\tfrac{1}{6}+o(1)\right)n^{3/2} \le \log \mathrm{Vol}(\mathcal{M}_n)\le O(n^{3/2}). Second, when sampling a metric space from Mn\mathcal{M}_n uniformly at random, the minimum distance is at least 1nc1 - n^{-c} with high probability, for some c>0c > 0. Our proof is based on entropy techniques. We discuss alternative approaches to estimating the volume of Mn\mathcal{M}_n using exchangeability, Szemer\'edi's regularity lemma, the hypergraph container method, and the K\H{o}v\'ari--S\'os--Tur\'an theorem.

Keywords

Cite

@article{arxiv.2104.01689,
  title  = {What does a typical metric space look like?},
  author = {Gady Kozma and Tom Meyerovitch and Ron Peled and Wojciech Samotij},
  journal= {arXiv preprint arXiv:2104.01689},
  year   = {2022}
}

Comments

64 pages, 2 figures. v2: Swapped Sections 5 and 6 and added a reader's guide

R2 v1 2026-06-24T00:50:37.530Z