Learning Similarity Metrics for Volumetric Simulations with Multiscale CNNs

Authors

  • Georg Kohl Technical University of Munich
  • Li-Wei Chen Technical University of Munich
  • Nils Thuerey Technical University of Munich

DOI:

https://doi.org/10.1609/aaai.v37i7.26007

Keywords:

ML: Learning Preferences or Rankings, APP: Natural Sciences, ML: Representation Learning, ML: Applications

Abstract

Simulations that produce three-dimensional data are ubiquitous in science, ranging from fluid flows to plasma physics. We propose a similarity model based on entropy, which allows for the creation of physically meaningful ground truth distances for the similarity assessment of scalar and vectorial data, produced from transport and motion-based simulations. Utilizing two data acquisition methods derived from this model, we create collections of fields from numerical PDE solvers and existing simulation data repositories. Furthermore, a multiscale CNN architecture that computes a volumetric similarity metric (VolSiM) is proposed. To the best of our knowledge this is the first learning method inherently designed to address the challenges arising for the similarity assessment of high-dimensional simulation data. Additionally, the tradeoff between a large batch size and an accurate correlation computation for correlation-based loss functions is investigated, and the metric's invariance with respect to rotation and scale operations is analyzed. Finally, the robustness and generalization of VolSiM is evaluated on a large range of test data, as well as a particularly challenging turbulence case study, that is close to potential real-world applications.

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Published

2023-06-26

How to Cite

Kohl, G., Chen, L.-W., & Thuerey, N. (2023). Learning Similarity Metrics for Volumetric Simulations with Multiscale CNNs. Proceedings of the AAAI Conference on Artificial Intelligence, 37(7), 8351-8359. https://doi.org/10.1609/aaai.v37i7.26007

Issue

Section

AAAI Technical Track on Machine Learning II