Čech–Delaunay gradient flow and homology inference for self-maps

U. Bauer; H. Edelsbrunner; G. Jabłoński; M. Mrozek

doi:10.1007/s41468-020-00058-8

Čech–Delaunay gradient flow and homology inference for self-maps

U. Bauer
, H. Edelsbrunner
, G. Jabłoński
, M. Mrozek

Associate Professorship of Applied Topology and Geometry

Institute of Science and Technology Austria (ISTA)
Jagiellonian University

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

We call a continuous self-map that reveals itself through a discrete set of point-value pairs a sampled dynamical system. Capturing the available information with chain maps on Delaunay complexes, we use persistent homology to quantify the evidence of recurrent behavior. We establish a sampling theorem to recover the eigenspaces of the endomorphism on homology induced by the self-map. Using a combinatorial gradient flow arising from the discrete Morse theory for Čech and Delaunay complexes, we construct a chain map to transform the problem from the natural but expensive Čech complexes to the computationally efficient Delaunay triangulations. The fast chain map algorithm has applications beyond dynamical systems.

Original language	English
Pages (from-to)	455-480
Number of pages	26
Journal	Journal of Applied and Computational Topology
Volume	4
Issue number	4
DOIs	https://doi.org/10.1007/s41468-020-00058-8
State	Published - Dec 2020

Keywords

Computational topology
Dynamical systems
Persistent homology

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10.1007/s41468-020-00058-8

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abstract = "We call a continuous self-map that reveals itself through a discrete set of point-value pairs a sampled dynamical system. Capturing the available information with chain maps on Delaunay complexes, we use persistent homology to quantify the evidence of recurrent behavior. We establish a sampling theorem to recover the eigenspaces of the endomorphism on homology induced by the self-map. Using a combinatorial gradient flow arising from the discrete Morse theory for {\v C}ech and Delaunay complexes, we construct a chain map to transform the problem from the natural but expensive {\v C}ech complexes to the computationally efficient Delaunay triangulations. The fast chain map algorithm has applications beyond dynamical systems.",

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AU - Edelsbrunner, H.

AU - Jabłoński, G.

AU - Mrozek, M.

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N2 - We call a continuous self-map that reveals itself through a discrete set of point-value pairs a sampled dynamical system. Capturing the available information with chain maps on Delaunay complexes, we use persistent homology to quantify the evidence of recurrent behavior. We establish a sampling theorem to recover the eigenspaces of the endomorphism on homology induced by the self-map. Using a combinatorial gradient flow arising from the discrete Morse theory for Čech and Delaunay complexes, we construct a chain map to transform the problem from the natural but expensive Čech complexes to the computationally efficient Delaunay triangulations. The fast chain map algorithm has applications beyond dynamical systems.

AB - We call a continuous self-map that reveals itself through a discrete set of point-value pairs a sampled dynamical system. Capturing the available information with chain maps on Delaunay complexes, we use persistent homology to quantify the evidence of recurrent behavior. We establish a sampling theorem to recover the eigenspaces of the endomorphism on homology induced by the self-map. Using a combinatorial gradient flow arising from the discrete Morse theory for Čech and Delaunay complexes, we construct a chain map to transform the problem from the natural but expensive Čech complexes to the computationally efficient Delaunay triangulations. The fast chain map algorithm has applications beyond dynamical systems.

KW - Computational topology

KW - Dynamical systems

KW - Persistent homology

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JO - Journal of Applied and Computational Topology

JF - Journal of Applied and Computational Topology

IS - 4

ER -

Čech–Delaunay gradient flow and homology inference for self-maps

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Keywords

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