Higher-order finite element approximation of the dynamic Laplacian

Nathanael Schilling; Gary Froyland; Oliver Junge

doi:10.1051/m2an/2020027

Higher-order finite element approximation of the dynamic Laplacian

Nathanael Schilling, Gary Froyland, Oliver Junge

Associate Professorship of Numerics of Complex Systems

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

3 Scopus citations

Abstract

The dynamic Laplace operator arises from extending problems of isoperimetry from fixed manifolds to manifolds evolved by general nonlinear dynamics. Eigenfunctions of this operator are used to identify and track finite-time coherent sets, which physically manifest in fluid flows as jets, vortices, and more complicated structures. Two robust and efficient finite-element discretisation schemes for numerically computing the dynamic Laplacian were proposed in Froyland and Junge [SIAM J. Appl. Dyn. Syst. 17 (2018) 1891-1924]. In this work we consider higher-order versions of these two numerical schemes and analyse them experimentally. We also prove the numerically computed eigenvalues and eigenvectors converge to the true objects for both schemes under certain assumptions. We provide an efficient implementation of the higher-order element schemes in an accompanying Julia package.

Original language	English
Pages (from-to)	1777-1795
Number of pages	19
Journal	Mathematical Modelling and Numerical Analysis
Volume	54
Issue number	5
DOIs	https://doi.org/10.1051/m2an/2020027
State	Published - 1 Sep 2020

Keywords

Dynamic Laplacian
Finite elements
Finite-time coherent sets
Transfer operator

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10.1051/m2an/2020027

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AU - Froyland, Gary

AU - Junge, Oliver

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N2 - The dynamic Laplace operator arises from extending problems of isoperimetry from fixed manifolds to manifolds evolved by general nonlinear dynamics. Eigenfunctions of this operator are used to identify and track finite-time coherent sets, which physically manifest in fluid flows as jets, vortices, and more complicated structures. Two robust and efficient finite-element discretisation schemes for numerically computing the dynamic Laplacian were proposed in Froyland and Junge [SIAM J. Appl. Dyn. Syst. 17 (2018) 1891-1924]. In this work we consider higher-order versions of these two numerical schemes and analyse them experimentally. We also prove the numerically computed eigenvalues and eigenvectors converge to the true objects for both schemes under certain assumptions. We provide an efficient implementation of the higher-order element schemes in an accompanying Julia package.

AB - The dynamic Laplace operator arises from extending problems of isoperimetry from fixed manifolds to manifolds evolved by general nonlinear dynamics. Eigenfunctions of this operator are used to identify and track finite-time coherent sets, which physically manifest in fluid flows as jets, vortices, and more complicated structures. Two robust and efficient finite-element discretisation schemes for numerically computing the dynamic Laplacian were proposed in Froyland and Junge [SIAM J. Appl. Dyn. Syst. 17 (2018) 1891-1924]. In this work we consider higher-order versions of these two numerical schemes and analyse them experimentally. We also prove the numerically computed eigenvalues and eigenvectors converge to the true objects for both schemes under certain assumptions. We provide an efficient implementation of the higher-order element schemes in an accompanying Julia package.

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KW - Finite elements

KW - Finite-time coherent sets

KW - Transfer operator

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Higher-order finite element approximation of the dynamic Laplacian

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