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[GSI 2023] Learning Lagrangian Fluid Mechanics with E(3)-Equivariant GNNs

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Learning Lagrangian Fluid Mechanics with E(3)-Equivariant Graph Neural Networks

Jax implementation of:

Learning Lagrangian Fluid Mechanics with E(3)-Equivariant GNNs
Artur P. Toshev, Gianluca Galletti, Johannes Brandstetter, Stefan Adami and Nikolaus A. Adams.
https://arxiv.org/abs/2305.15603

Left: time snapshots of velocity magnitude of Taylor-Green vortex flow (top), reverse Poiseuille flow (bottom). Right: attribute embedding model (top), effect of different embedding strategies on velocity (bottom).

Abstract: We contribute to the vastly growing field of machine learning for engineering systems by demonstrating that equivariant graph neural networks have the potential to learn more accurate dynamic-interaction models than their non-equivariant counterparts. We benchmark two well-studied fluid-flow systems, namely 3D decaying Taylor-Green vortex and 3D reverse Poiseuille flow, and evaluate the models based on different performance measures, such as kinetic energy or Sinkhorn distance. In addition, we investigate different embedding methods of physical-information histories for equivariant models. We find that while currently being rather slow to train and evaluate, equivariant models with our proposed history embeddings learn more accurate physical interactions.

Installation

This work is built on top of LagrangeBench, a machine learning benchmarking suite for particle fluid problems. First install the requirements

pip install lagrangebench
# (optional) gpu support
pip install --upgrade jax[cuda11_pip] -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html

For CUDA 12 simply replace cuda11_pip with cuda12_pip.

Or alternatively follow the instructions in LagrangeBench

Usage

Training

For example, to train a HAE-SEGNN model with linear attribute embeddings from scratch on the Taylor-Green vortex flow dataset run

python main.py --dataset tgv --model haesegnn --hae_mode lin --mode train

Note: The first time you run the code, the specified dataset is automatically downloaded in datasets/.

Similarly, to evaluate a trained model run (the correct argument configuration must be passed)

python main.py --dataset tgv --model_dir <path to checkpoint> --mode infer

Citing

This codebase was created by Artur Toshev and Gianluca Galletti. If you find it useful, please cite it.

@misc{toshev2023learning,
      title={Learning Lagrangian Fluid Mechanics with E($3$)-Equivariant Graph Neural Networks}, 
      author={Artur P. Toshev and Gianluca Galletti and Johannes Brandstetter and Stefan Adami and Nikolaus A. Adams},
      year={2023},
      eprint={2305.15603},
      archivePrefix={arXiv},
      primaryClass={cs.LG}
}

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