English

Universal diameter bounds for random graphs with given degrees

Probability 2025-12-08 v3 Combinatorics

Abstract

Given a graph GG, let diam(G)\mathrm{diam}(G) be the greatest distance between any two vertices of GG which lie in the same connected component, and let diam+(G)\mathrm{diam}^+(G) be the greatest distance between any two vertices of GG; so diam+(G)=\mathrm{diam}^+(G)=\infty if GG is not connected. Fix a sequence (d1,,dn)(d_1,\ldots,d_n) of positive integers, and let G\mathbf{G} be a uniformly random connected simple graph with V(G)=[n]:={1,,n}V(\mathbf{G})=[n]:=\{1,\ldots,n\} such that degG(v)=dv\mathrm{deg}_{\mathbf{G}}(v)=d_v for all v[n]v \in [n]. We show that, unless a 1o(1)1-o(1) proportion of vertices have degree 22, then E[diam(G)]=O(n)\mathbb{E}[\mathrm{diam}(\mathbf{G})]=O(\sqrt{n}). It is not hard to see that this bound is best possible for general degree sequences (and in particular in the case of trees, in which v=1ndv=2(n1)\sum_{v=1}^n d_v = 2(n-1)). We also prove that this bound holds without the connectivity constraint. As a key input to the proofs, we show that graphs with minimum degree 33 are with high probability connected and have logarithmic diameter: if min(d1,,dn)3\min(d_1,\ldots,d_n) \ge 3 and G\mathbf{G} is a uniformly random simple graph with V(G)=[n]V(\mathbf{G})=[n] such that degG(v)=dv\mathrm{deg}_{\mathbf{G}}(v)=d_v for all v[n]v \in [n], then diam+(G)=\mathrm{diam}^+(\mathbf{G})= OP(logn)O_{\mathbb{P}}(\log n); this bound is also best possible.

Keywords

Cite

@article{arxiv.2507.10759,
  title  = {Universal diameter bounds for random graphs with given degrees},
  author = {Louigi Addario-Berry and Gabriel Crudele},
  journal= {arXiv preprint arXiv:2507.10759},
  year   = {2025}
}

Comments

48 pages, 2 figures

R2 v1 2026-07-01T04:01:10.391Z