English

The evolution of random graphs on surfaces

Combinatorics 2017-12-18 v2

Abstract

For integers g,m0g,m \geq 0 and n>0n>0, let Sg(n,m)S_{g}(n,m) denote the graph taken uniformly at random from the set of all graphs on {1,2,,n}\{1,2, \ldots, n\} with exactly m=m(n)m=m(n) edges and with genus at most gg. We use counting arguments to investigate the components, subgraphs, maximum degree, and largest face size of Sg(n,m)S_{g}(n,m), finding that there is often different asymptotic behaviour depending on the ratio mn\frac{m}{n}. In our main results, we show that the probability that Sg(n,m)S_{g}(n,m) contains any given non-planar component converges to 00 as nn \to \infty for all m(n)m(n); the probability that Sg(n,m)S_{g}(n,m) contains a copy of any given planar graph converges to 11 as nn \to \infty if lim infmn>1\liminf \frac{m}{n} > 1; the maximum degree of Sg(n,m)S_{g}(n,m) is Θ(lnn)\Theta (\ln n) with high probability if lim infmn>1\liminf \frac{m}{n} > 1; and the largest face size of Sg(n,m)S_{g}(n,m) has a threshold around mn=1\frac{m}{n}=1 where it changes from Θ(n)\Theta (n) to Θ(lnn)\Theta (\ln n) with high probability.

Keywords

Cite

@article{arxiv.1709.00864,
  title  = {The evolution of random graphs on surfaces},
  author = {Chris Dowden and Mihyun Kang and Philipp Sprüssel},
  journal= {arXiv preprint arXiv:1709.00864},
  year   = {2017}
}

Comments

35 pages

R2 v1 2026-06-22T21:32:11.458Z