Model order reduction for the 1D Boltzmann-BGK equation: identifying intrinsic variables using neural networks

Julian Koellermeier*, Philipp Krah, Julius Reiss, Zachary Schellin

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

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Abstract

Kinetic equations are crucial for modeling non-equilibrium phenomena, but their computational complexity is a challenge. This paper presents a data-driven approach using reduced order models (ROM) to efficiently model non-equilibrium flows in kinetic equations by comparing two ROM approaches: proper orthogonal decomposition (POD) and autoencoder neural networks (AE). While AE initially demonstrate higher accuracy, POD’s precision improves as more modes are considered. Notably, our work recognizes that the classical POD model order reduction approach, although capable of accurately representing the non-linear solution manifold of the kinetic equation, may not provide a parsimonious model of the data due to the inherently non-linear nature of the data manifold. We demonstrate how AEs are used in finding the intrinsic dimension of a system and to allow correlating the intrinsic quantities with macroscopic quantities that have a physical interpretation.

Original languageEnglish
Article number16
Number of pages24
JournalMicrofluidics and Nanofluidics
Volume28
Issue number3
DOIs
Publication statusPublished - Mar-2024

Keywords

  • Boltzmann-BGK
  • Data-driven methods
  • Kinetic equations
  • Model order reduction
  • Neural autoencoder networks
  • Proper orthogonal decomposition
  • Sod shock tube

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