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Multiscale graph neural network autoencoders for interpretable scientific machine learning.

Authors :
Barwey, Shivam
Shankar, Varun
Viswanathan, Venkatasubramanian
Maulik, Romit
Source :
Journal of Computational Physics. Dec2023, Vol. 495, pN.PAG-N.PAG. 1p.
Publication Year :
2023

Abstract

The goal of this work is to address two limitations in autoencoder-based models: latent space interpretability and compatibility with unstructured meshes. This is accomplished here with the development of a novel graph neural network (GNN) autoencoding architecture with demonstrations on complex fluid flow applications. To address the first goal of interpretability, the GNN autoencoder achieves reduction in the number nodes in the encoding stage through an adaptive graph reduction procedure. This reduction procedure essentially amounts to flowfield-conditioned node sampling and sensor identification, and produces interpretable latent graph representations tailored to the flowfield reconstruction task in the form of so-called masked fields. These masked fields allow the user to (a) visualize where in physical space a given latent graph is active, and (b) interpret the time-evolution of the latent graph connectivity in accordance with the time-evolution of unsteady flow features (e.g. recirculation zones, shear layers) in the domain. To address the goal of unstructured mesh compatibility, the autoencoding architecture utilizes a series of multi-scale message passing (MMP) layers, each of which models information exchange among node neighborhoods at various lengthscales. The MMP layer, which augments standard single-scale message passing with learnable coarsening operations, allows the decoder to more efficiently reconstruct the flowfield from the identified regions in the masked fields. Analysis of latent graphs produced by the autoencoder for various model settings are conducted using unstructured snapshot data sourced from large-eddy simulations in a backward-facing step (BFS) flow configuration with an OpenFOAM-based flow solver at high Reynolds numbers. • A graph neural network autoencoder is developed for latent space interpretability. • Latent graphs can be accessed as time-evolving coherent structures in physical space. • Multi-scale message passing layers are employed to improve reconstructions. • Demonstrations performed using unstructured unsteady turbulent fluid flow dataset. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00219991
Volume :
495
Database :
Academic Search Index
Journal :
Journal of Computational Physics
Publication Type :
Academic Journal
Accession number :
173434809
Full Text :
https://doi.org/10.1016/j.jcp.2023.112537