English

Minimum weight disk triangulations and fillings

Probability 2019-11-11 v1 Combinatorics

Abstract

We study the minimum total weight of a disk triangulation using vertices out of {1,,n}\{1,\ldots,n\}, where the boundary is the triangle (123)(123) and the (n3)\binom{n}3 triangles have independent weights, e.g. Exp(1)\mathrm{Exp}(1) or U(0,1)\mathrm{U}(0,1). We show that for explicit constants c1,c2>0c_1,c_2>0, this minimum is c1lognn+c2loglognn+Ynnc_1 \frac{\log n}{\sqrt n} + c_2 \frac{\log\log n}{\sqrt n} + \frac{Y_n}{\sqrt n} where the random variable YnY_n is tight, and it is attained by a triangulation that consists of 14logn+OP(logn)\frac14\log n + O_P(\sqrt{\log n}) vertices. Moreover, for disk triangulations that are canonical, in that no inner triangle contains all but O(1)O(1) of the vertices, the minimum weight has the above form with the law of YnY_n converging weakly to a shifted~Gumbel. In addition, we prove that, with high probability, the minimum weights of a homological filling and a homotopical filling of the cycle (123)(123) are both attained by the minimum weight disk triangulation.

Cite

@article{arxiv.1911.02569,
  title  = {Minimum weight disk triangulations and fillings},
  author = {Itai Benjamini and Eyal Lubetzky and Yuval Peled},
  journal= {arXiv preprint arXiv:1911.02569},
  year   = {2019}
}

Comments

16 pages, 2 figures

R2 v1 2026-06-23T12:07:47.876Z