Cech Closure Spaces: A Unified Framework for Discrete and Continuous Homotopy

TL;DR

This paper develops a unified homotopy theory framework for Cech closure spaces, applying it to metric spaces, graphs, and simplicial complexes, with implications for topological data analysis and combinatorics.

Contribution

It introduces new Cech closure structures on various spaces, establishing a comprehensive homotopy theory, including a Seifert-van Kampen theorem and persistent homotopy concepts.

Findings

Defined non-trivial homotopy theory for finite metric spaces

Constructed combinatorial homotopy theories for graphs and complexes

Calculated fundamental groups for specific closure-structured spaces

Abstract

Motivated by constructions in topological data analysis and algebraic combinatorics, we study homotopy theory on the category of Cech closure spaces $\mathbf{Cl}$, the category whose objects are sets endowed with a Cech closure operator and whose morphisms are the continuous maps between them. We introduce new classes of Cech closure structures on metric spaces, graphs, and simplicial complexes, and we show how each of these cases gives rise to an interesting homotopy theory. In particular, we show that there exists a natural family of Cech closure structures on metric spaces which produces a non-trivial homotopy theory for finite metric spaces, i.e. point clouds, the spaces of interest in topological data analysis. We then give a Cech closure structure to graphs and simplicial complexes which may be used to construct a new combinatorial (as opposed to topological) homotopy theory for each skeleton of those spaces. We further show that there is a Seifert-van Kampen theorem for closure spaces, a well-defined notion of persistent homotopy, and an associated interleaving distance. As an illustration of the difference with the topological setting, we calculate the fundamental group for the circle, `circular graphs', and the wedge of circles endowed with different closure structures. Finally, we produce a continuous map from the topological circle to `circular graphs' which, given the appropriate closure structures, induces an isomorphism on the fundamental groups.