Error-Correcting Neural Networks for Semi-Lagrangian Advection in the
Level-Set Method
- URL: http://arxiv.org/abs/2110.11611v1
- Date: Fri, 22 Oct 2021 06:36:15 GMT
- Title: Error-Correcting Neural Networks for Semi-Lagrangian Advection in the
Level-Set Method
- Authors: Luis \'Angel Larios-C\'ardenas and Fr\'ed\'eric Gibou
- Abstract summary: We present a machine learning framework that blends image super-resolution technologies with scalar transport in the level-set method.
We investigate whether we can compute on-the-fly data-driven corrections to minimize numerical viscosity in the coarse-mesh evolution of an interface.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We present a machine learning framework that blends image super-resolution
technologies with scalar transport in the level-set method. Here, we
investigate whether we can compute on-the-fly data-driven corrections to
minimize numerical viscosity in the coarse-mesh evolution of an interface. The
proposed system's starting point is the semi-Lagrangian formulation. And, to
reduce numerical dissipation, we introduce an error-quantifying multilayer
perceptron. The role of this neural network is to improve the numerically
estimated surface trajectory. To do so, it processes localized level-set,
velocity, and positional data in a single time frame for select vertices near
the moving front. Our main contribution is thus a novel
machine-learning-augmented transport algorithm that operates alongside
selective redistancing and alternates with conventional advection to keep the
adjusted interface trajectory smooth. Consequently, our procedure is more
efficient than full-scan convolutional-based applications because it
concentrates computational effort only around the free boundary. Also, we show
through various tests that our strategy is effective at counteracting both
numerical diffusion and mass loss. In passive advection problems, for example,
our method can achieve the same precision as the baseline scheme at twice the
resolution but at a fraction of the cost. Similarly, our hybrid technique can
produce feasible solidification fronts for crystallization processes. On the
other hand, highly deforming or lengthy simulations can precipitate bias
artifacts and inference deterioration. Likewise, stringent design velocity
constraints can impose certain limitations, especially for problems involving
rapid interface changes. In the latter cases, we have identified several
opportunity avenues to enhance robustness without forgoing our approach's basic
concept.
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