English

Supercritical minimum mean-weight cycles

Probability 2015-04-06 v1

Abstract

We study the weight and length of the minimum mean-weight cycle in the stochastic mean-field distance model, i.e., in the complete graph on nn vertices with edges weighted by independent exponential random variables. Mathieu and Wilson showed that the minimum mean-weight cycle exhibits one of two distinct behaviors, according to whether its mean weight is smaller or larger than 1/(ne)1/(ne); and that both scenarios occur with positive probability in the limit nn\to\infty. If the mean weight is <1/(ne)< 1/(ne), the length is of constant order. If the mean weight is >1/(ne)> 1/(ne), it is concentrated just above 1/(ne)1/(n e), and the length diverges with nn. The analysis of Mathieu--Wilson gives a detailed characterization of the subcritical regime, including the (non-degenerate) limiting distributions of the weight and length, but leaves open the supercritical behavior. We determine the asymptotics for the supercritical regime, showing that with high probability, the minimum mean weight is (ne)1[1+π2/(2log2n)+O((logn)3)](n e)^{-1}[1 + \pi^2/(2 \log^2 n) + O((\log n)^{-3})], and the cycle achieving this minimum has length on the order of (logn)3(\log n)^3.

Cite

@article{arxiv.1504.00918,
  title  = {Supercritical minimum mean-weight cycles},
  author = {Jian Ding and Nike Sun and David B. Wilson},
  journal= {arXiv preprint arXiv:1504.00918},
  year   = {2015}
}

Comments

28 pages, 5 figures

R2 v1 2026-06-22T09:09:46.970Z