English

Curvature Sets Over Persistence Diagrams

Algebraic Topology 2023-07-26 v5 Metric Geometry

Abstract

We study a family of invariants of compact metric spaces that combines the Curvature Sets defined by Gromov in the 1980s with Vietoris-Rips Persistent Homology. For given integers k0k\geq 0 and n1n\geq 1 we consider the dimension kk Vietoris-Rips persistence diagrams of \emph{all} subsets of a given metric space with cardinality at most nn. We call these invariants \emph{persistence sets} and denote them as Dn,kVR\mathbf{D}_{n,k}^\textrm{VR}. We establish that (1) computing these invariants is often significantly more efficient than computing the usual Vietoris-Rips persistence diagrams, (2) these invariants have very good discriminating power and, in many cases, capture information that is imperceptible through standard Vietoris-Rips persistence diagrams, and (3) they enjoy stability properties. We precisely characterize some of them in the case of spheres and surfaces with constant curvature using a generalization of Ptolemy's inequality. We also identify a rich family of metric graphs for which D4,1VR\mathbf{D}_{4,1}^\textrm{VR} fully recovers their homotopy type by studying split-metric decompositions. Along the way we prove some useful properties of Vietoris-Rips persistence diagrams using Mayer-Vietoris sequences. These yield a geometric algorithm for computing the Vietoris-Rips persistence diagram of a space XX with cardinality 2k+22k+2 with quadratic time complexity as opposed to the much higher cost incurred by the usual algebraic algorithms relying on matrix reduction.

Keywords

Cite

@article{arxiv.2103.04470,
  title  = {Curvature Sets Over Persistence Diagrams},
  author = {Mario Gómez and Facundo Mémoli},
  journal= {arXiv preprint arXiv:2103.04470},
  year   = {2023}
}

Comments

Added Example 4.15 (in Section 4.3) to show that persistence sets and persistent homology distinguish different spaces, and added more running time comparisons to Section 4.4

R2 v1 2026-06-23T23:51:31.066Z