English

Polyhedral computational geometry for averaging metric phylogenetic trees

Metric Geometry 2014-02-18 v2 Computational Geometry Combinatorics Statistics Theory Populations and Evolution Statistics Theory

Abstract

This paper investigates the computational geometry relevant to calculations of the Frechet mean and variance for probability distributions on the phylogenetic tree space of Billera, Holmes and Vogtmann, using the theory of probability measures on spaces of nonpositive curvature developed by Sturm. We show that the combinatorics of geodesics with a specified fixed endpoint in tree space are determined by the location of the varying endpoint in a certain polyhedral subdivision of tree space. The variance function associated to a finite subset of tree space has a fixed CC^\infty algebraic formula within each cell of the corresponding subdivision, and is continuously differentiable in the interior of each orthant of tree space. We use this subdivision to establish two iterative methods for producing sequences that converge to the Frechet mean: one based on Sturm's Law of Large Numbers, and another based on descent algorithms for finding optima of smooth functions on convex polyhedra. We present properties and biological applications of Frechet means and extend our main results to more general globally nonpositively curved spaces composed of Euclidean orthants.

Keywords

Cite

@article{arxiv.1211.7046,
  title  = {Polyhedral computational geometry for averaging metric phylogenetic trees},
  author = {Ezra Miller and Megan Owen and J. Scott Provan},
  journal= {arXiv preprint arXiv:1211.7046},
  year   = {2014}
}

Comments

43 pages, 6 figures; v2: fixed typos, shortened Sections 1 and 5, added counter example for polyhedrality of vistal subdivision in general CAT(0) cubical complexes; v1: 43 pages, 5 figures

R2 v1 2026-06-21T22:46:23.855Z