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Main Authors: Faraji, Farbod, Reza, Maryam, Knoll, Aaron, Kutz, J. Nathan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.01532
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author Faraji, Farbod
Reza, Maryam
Knoll, Aaron
Kutz, J. Nathan
author_facet Faraji, Farbod
Reza, Maryam
Knoll, Aaron
Kutz, J. Nathan
contents Real-world systems often exhibit dynamics influenced by various parameters, either inherent or externally controllable, necessitating models capable of reliably capturing these parametric behaviors. Plasma technologies exemplify such systems. For example, phenomena governing global dynamics in Hall thrusters (a spacecraft propulsion technology) vary with various parameters, such as the "self-sustained electric field". In this Part II, following on the introduction of our novel data-driven local operator finding algorithm, Phi Method, in Part I, we showcase the method's effectiveness in learning parametric dynamics to predict system behavior across unseen parameter spaces. We present two adaptations: the "parametric Phi Method" and the "ensemble Phi Method", which are demonstrated through 2D fluid-flow-past-a-cylinder and 1D Hall-thruster-plasma-discharge problems. Comparative evaluation against parametric OPT-DMD in the fluid case demonstrates superior predictive performance of the parametric Phi Method. Across both test cases, parametric and ensemble Phi Method reliably recover governing parametric PDEs and offer accurate predictions over test parameters. Ensemble ROM analysis underscores Phi Method's robust learning of dominant dynamic coefficients with high confidence.
format Preprint
id arxiv_https___arxiv_org_abs_2403_01532
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Data-driven local operator finding for reduced-order modelling of plasma systems: II. Application to parametric dynamics
Faraji, Farbod
Reza, Maryam
Knoll, Aaron
Kutz, J. Nathan
Plasma Physics
Machine Learning
Computational Physics
Real-world systems often exhibit dynamics influenced by various parameters, either inherent or externally controllable, necessitating models capable of reliably capturing these parametric behaviors. Plasma technologies exemplify such systems. For example, phenomena governing global dynamics in Hall thrusters (a spacecraft propulsion technology) vary with various parameters, such as the "self-sustained electric field". In this Part II, following on the introduction of our novel data-driven local operator finding algorithm, Phi Method, in Part I, we showcase the method's effectiveness in learning parametric dynamics to predict system behavior across unseen parameter spaces. We present two adaptations: the "parametric Phi Method" and the "ensemble Phi Method", which are demonstrated through 2D fluid-flow-past-a-cylinder and 1D Hall-thruster-plasma-discharge problems. Comparative evaluation against parametric OPT-DMD in the fluid case demonstrates superior predictive performance of the parametric Phi Method. Across both test cases, parametric and ensemble Phi Method reliably recover governing parametric PDEs and offer accurate predictions over test parameters. Ensemble ROM analysis underscores Phi Method's robust learning of dominant dynamic coefficients with high confidence.
title Data-driven local operator finding for reduced-order modelling of plasma systems: II. Application to parametric dynamics
topic Plasma Physics
Machine Learning
Computational Physics
url https://arxiv.org/abs/2403.01532