Unsupervised machine-learning shock-capturing technique for high-order
solvers
- URL: http://arxiv.org/abs/2308.00086v2
- Date: Mon, 7 Aug 2023 16:04:02 GMT
- Title: Unsupervised machine-learning shock-capturing technique for high-order
solvers
- Authors: Andr\'es Mateo-Gab\'in, Kenza Tlales, Eusebio Valero, Esteban Ferrer,
Gonzalo Rubio
- Abstract summary: We present a novel unsupervised machine learning shock capturing algorithm based on Gaussian Mixture Models (GMMs)
The proposed GMM sensor demonstrates remarkable accuracy in detecting shocks and is robust across diverse test cases without the need for parameter tuning.
Our study reveals the potential of unsupervised machine learning methods, exemplified by the GMM sensor, to improve the robustness and efficiency of advanced CFD codes.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We present a novel unsupervised machine learning shock capturing algorithm
based on Gaussian Mixture Models (GMMs). The proposed GMM sensor demonstrates
remarkable accuracy in detecting shocks and is robust across diverse test cases
without the need for parameter tuning. We compare the GMM-based sensor with
state-of-the-art alternatives. All methods are integrated into a high-order
compressible discontinuous Galerkin solver where artificial viscosity can be
modulated to capture shocks. Supersonic test cases, including high Reynolds
numbers, showcase the sensor's performance, demonstrating the same
effectiveness as fine-tuned state-of-the-art sensors. %The nodal DG aproach
allows for potential applications in sub-cell flux-differencing formulations,
supersonic feature detection, and mesh refinement. The adaptive nature and
ability to function without extensive training datasets make this GMM-based
sensor suitable for complex geometries and varied flow configurations. Our
study reveals the potential of unsupervised machine learning methods,
exemplified by the GMM sensor, to improve the robustness and efficiency of
advanced CFD codes.
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