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Lagrangian large eddy simulations via physics-informed machine learning.

Yifeng Tian1, Michael Woodward2,3, Mikhail Stepanov2

  • 1Information Sciences Group, Computer, Computational and Statistical Sciences Division (CCS-3), Los Alamos National Laboratory, Los Alamos, NM 87545.

Proceedings of the National Academy of Sciences of the United States of America
|August 16, 2023
PubMed
Summary
This summary is machine-generated.

This study introduces Lagrangian Large Eddy Simulation (L-LES), a novel approach to modeling fluid turbulence using Lagrangian particles and machine learning. L-LES accurately reproduces turbulence statistics and structures, offering an alternative to traditional Eulerian methods.

Keywords:
Lagrangian particleslarge eddy simulationphysics-informed machine learningturbulence modeling

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Area of Science:

  • Computational Fluid Dynamics
  • Turbulence Modeling
  • Machine Learning Applications

Background:

  • High-Reynolds number homogeneous isotropic turbulence (HIT) is governed by the Navier-Stokes (NS) equations, which are computationally challenging to solve.
  • Traditional Large Eddy Simulation (LES) relies on Eulerian velocity fields and assumptions about subgrid-scale effects.
  • A need exists for alternative turbulence modeling approaches that capture both Eulerian and Lagrangian flow characteristics.

Purpose of the Study:

  • To develop a novel Lagrangian Large Eddy Simulation (L-LES) framework for modeling turbulence.
  • To utilize Machine Learning (ML) for training and resolving L-LES equations based on direct numerical simulation (DNS) data.
  • To incorporate physics-informed parameterization and neural networks for accurate turbulence evolution modeling.

Main Methods:

  • Developed L-LES heuristics based on Lagrangian particle dynamics, generalizing smoothed particle hydrodynamics.
  • Employed Machine Learning (ML) for training L-LES models using Lagrangian data from NS-DNS.
  • Integrated physics-informed parameterization and neural networks within a differentiable programming framework.
  • Utilized various loss functions, including physics-informed options, for efficient model training.

Main Results:

  • The L-LES model successfully reproduced Eulerian and unique Lagrangian turbulence structures and statistics.
  • The model demonstrated capability across a range of turbulent Mach numbers.
  • Physics-informed ML training facilitated efficient and accurate turbulence evolution prediction.

Conclusions:

  • L-LES offers a viable and accurate alternative to traditional Eulerian LES for turbulence simulation.
  • The integration of Lagrangian methods with ML provides a powerful new tool for computational fluid dynamics.
  • This physics-informed ML approach advances the modeling of subgrid-scale effects in turbulent flows.