Data-driven eigensolution analysis based on a spatio-temporal Koopman decomposition, with applications to high-order methods

Jiaqing Kou; Soledad Le Clainche; Esteban Ferrer

doi:10.1016/j.jcp.2021.110798

Data-driven eigensolution analysis based on a spatio-temporal Koopman decomposition, with applications to high-order methods

Jiaqing Kou, Soledad Le Clainche, Esteban Ferrer

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

12 Scopus citations

Abstract

We propose a data-driven method to perform eigensolution analyses and quantify numerical errors in a non-intrusive manner. In classic eigensolution analysis methods, explicit matrices need to be constructed, whilst in our approach only solution snapshots from numerical simulations are required to quantify the numerical errors (dispersion and diffusion) in time and/or space. This new approach is based on a recent data-driven method: the Spatio-Temporal Koopman Decomposition (STKD), that approximates spatio-temporal data as a linear combination of standing or travelling waves growing or decaying exponentially in time and/or space. We validate our approach with classic matrix-based approaches, where accurate predictions of the dispersion-dissipation behaviour for both temporal and spatial eigensolution analyses are reported.

Original language	English
Article number	110798
Journal	Journal of Computational Physics
Volume	449
DOIs	https://doi.org/10.1016/j.jcp.2021.110798
State	Published - 15 Jan 2022
Externally published	Yes

Keywords

Data-driven methods
Dispersion-diffusion analysis
Eigensolution analysis
Flux reconstruction
Koopman analysis
Spectral/hp methods

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10.1016/j.jcp.2021.110798

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title = "Data-driven eigensolution analysis based on a spatio-temporal Koopman decomposition, with applications to high-order methods",

abstract = "We propose a data-driven method to perform eigensolution analyses and quantify numerical errors in a non-intrusive manner. In classic eigensolution analysis methods, explicit matrices need to be constructed, whilst in our approach only solution snapshots from numerical simulations are required to quantify the numerical errors (dispersion and diffusion) in time and/or space. This new approach is based on a recent data-driven method: the Spatio-Temporal Koopman Decomposition (STKD), that approximates spatio-temporal data as a linear combination of standing or travelling waves growing or decaying exponentially in time and/or space. We validate our approach with classic matrix-based approaches, where accurate predictions of the dispersion-dissipation behaviour for both temporal and spatial eigensolution analyses are reported.",

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AU - Le Clainche, Soledad

AU - Ferrer, Esteban

PY - 2022/1/15

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AB - We propose a data-driven method to perform eigensolution analyses and quantify numerical errors in a non-intrusive manner. In classic eigensolution analysis methods, explicit matrices need to be constructed, whilst in our approach only solution snapshots from numerical simulations are required to quantify the numerical errors (dispersion and diffusion) in time and/or space. This new approach is based on a recent data-driven method: the Spatio-Temporal Koopman Decomposition (STKD), that approximates spatio-temporal data as a linear combination of standing or travelling waves growing or decaying exponentially in time and/or space. We validate our approach with classic matrix-based approaches, where accurate predictions of the dispersion-dissipation behaviour for both temporal and spatial eigensolution analyses are reported.

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KW - Dispersion-diffusion analysis

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Data-driven eigensolution analysis based on a spatio-temporal Koopman decomposition, with applications to high-order methods

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Keywords

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