Shape Invariant 3D-Variational Autoencoder: Super Resolution in Turbulence flow

• URL: http://arxiv.org/abs/2507.22082v1
• Date: Sat, 26 Jul 2025 17:28:39 GMT
• Title: Shape Invariant 3D-Variational Autoencoder: Super Resolution in Turbulence flow
• Authors: Anuraj Maurya,
• Abstract summary: Deep learning provides a versatile suite of methods for extracting information from structured datasets, enabling deeper understanding of underlying fluid phenomena.<n>The field of turbulence modeling, in particular, benefits from the growing availability of high-dimensional data obtained through experiments, field observations, and large-scale simulations spanning multipletemporal dynamic scales.
• Score: 0.0
• License: http://creativecommons.org/licenses/by-nc-sa/4.0/
• Abstract: Deep learning provides a versatile suite of methods for extracting structured information from complex datasets, enabling deeper understanding of underlying fluid dynamic phenomena. The field of turbulence modeling, in particular, benefits from the growing availability of high-dimensional data obtained through experiments, field observations, and large-scale simulations spanning multiple spatio-temporal scales. This report presents a concise overview of both classical and deep learningbased approaches to turbulence modeling. It further investigates two specific challenges at the intersection of fluid dynamics and machine learning: the integration of multiscale turbulence models with deep learning architectures, and the application of deep generative models for super-resolution reconstruction

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