A Denoising Diffusion Model for Fluid Field Prediction
- URL: http://arxiv.org/abs/2301.11661v2
- Date: Mon, 30 Jan 2023 10:34:10 GMT
- Title: A Denoising Diffusion Model for Fluid Field Prediction
- Authors: Gefan Yang, Stefan Sommer
- Abstract summary: We propose a novel denoising diffusion generative model for predicting nonlinear fluid fields named FluidDiff.
By performing a diffusion process, the model is able to learn a complex representation of the high-dimensional dynamic system.
Langevin sampling is used to generate predictions for the flow state under specified initial conditions.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We propose a novel denoising diffusion generative model for predicting
nonlinear fluid fields named FluidDiff. By performing a diffusion process, the
model is able to learn a complex representation of the high-dimensional dynamic
system, and then Langevin sampling is used to generate predictions for the flow
state under specified initial conditions. The model is trained with finite,
discrete fluid simulation data. We demonstrate that our model has the capacity
to model the distribution of simulated training data and that it gives accurate
predictions on the test data. Without encoded prior knowledge of the underlying
physical system, it shares competitive performance with other deep learning
models for fluid prediction, which is promising for investigation on new
computational fluid dynamics methods.
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