Benchmarking of Deep Learning models on 2D Laminar Flow behind Cylinder

• URL: http://arxiv.org/abs/2205.13485v1
• Date: Thu, 26 May 2022 16:49:09 GMT
• Title: Benchmarking of Deep Learning models on 2D Laminar Flow behind Cylinder
• Authors: Mritunjay Musale, Vaibhav Vasani
• Abstract summary: Direct Numerical Simulation(DNS) is one of the tasks in Computational Fluid Dynamics. We train these three models in an autoencoder manner, for this the dataset is treated like sequential frames given to the model as input. We observe that recently introduced architecture called Transformer significantly outperforms its counterparts on the selected dataset.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: The rapidly advancing field of Fluid Mechanics has recently employed Deep Learning to solve various problems within that field. In that same spirit we try to perform Direct Numerical Simulation(DNS) which is one of the tasks in Computational Fluid Dynamics, using three fundamental architectures in the field of Deep Learning that were each used to solve various high dimensional problems. We train these three models in an autoencoder manner, for this the dataset is treated like sequential frames given to the model as input. We observe that recently introduced architecture called Transformer significantly outperforms its counterparts on the selected dataset.Furthermore, we conclude that using Transformers for doing DNS in the field of CFD is an interesting research area worth exploring.

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