English

Polynomial-Sized Topological Approximations Using The Permutahedron

Computational Geometry 2016-04-04 v2 Algebraic Topology

Abstract

Classical methods to model topological properties of point clouds, such as the Vietoris-Rips complex, suffer from the combinatorial explosion of complex sizes. We propose a novel technique to approximate a multi-scale filtration of the Rips complex with improved bounds for size: precisely, for nn points in Rd\mathbb{R}^d, we obtain a O(d)O(d)-approximation with at most n2O(dlogk)n2^{O(d \log k)} simplices of dimension kk or lower. In conjunction with dimension reduction techniques, our approach yields a O(polylog(n))O(\mathrm{polylog} (n))-approximation of size nO(1)n^{O(1)} for Rips filtrations on arbitrary metric spaces. This result stems from high-dimensional lattice geometry and exploits properties of the permutahedral lattice, a well-studied structure in discrete geometry. Building on the same geometric concept, we also present a lower bound result on the size of an approximate filtration: we construct a point set for which every (1+ϵ)(1+\epsilon)-approximation of the \v{C}ech filtration has to contain nΩ(loglogn)n^{\Omega(\log\log n)} features, provided that ϵ<1log1+cn\epsilon <\frac{1}{\log^{1+c} n} for c(0,1)c\in(0,1).

Keywords

Cite

@article{arxiv.1601.02732,
  title  = {Polynomial-Sized Topological Approximations Using The Permutahedron},
  author = {Aruni Choudhary and Michael Kerber and Sharath Raghvendra},
  journal= {arXiv preprint arXiv:1601.02732},
  year   = {2016}
}

Comments

24 pages, 1 figure

R2 v1 2026-06-22T12:27:29.979Z