Reconstructing Turbulent Flows Using Physics-Aware Spatio-Temporal
Dynamics and Test-Time Refinement
- URL: http://arxiv.org/abs/2304.12130v3
- Date: Tue, 12 Dec 2023 16:18:51 GMT
- Title: Reconstructing Turbulent Flows Using Physics-Aware Spatio-Temporal
Dynamics and Test-Time Refinement
- Authors: Shengyu Chen, Tianshu Bao, Peyman Givi, Can Zheng, Xiaowei Jia
- Abstract summary: We propose a new physics-guided neural network for reconstructing the sequential DNS from low-resolution LES data.
A Sim-based refinement method is also developed to enforce physical constraints and further reduce the accumulated reconstruction errors over long periods.
- Score: 10.711201734103073
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Simulating turbulence is critical for many societally important applications
in aerospace engineering, environmental science, the energy industry, and
biomedicine. Large eddy simulation (LES) has been widely used as an alternative
to direct numerical simulation (DNS) for simulating turbulent flows due to its
reduced computational cost. However, LES is unable to capture all of the scales
of turbulent transport accurately. Reconstructing DNS from low-resolution LES
is critical for many scientific and engineering disciplines, but it poses many
challenges to existing super-resolution methods due to the spatio-temporal
complexity of turbulent flows. In this work, we propose a new physics-guided
neural network for reconstructing the sequential DNS from low-resolution LES
data. The proposed method leverages the partial differential equation that
underlies the flow dynamics in the design of spatio-temporal model
architecture. A degradation-based refinement method is also developed to
enforce physical constraints and further reduce the accumulated reconstruction
errors over long periods. The results on two different types of turbulent flow
data confirm the superiority of the proposed method in reconstructing the
high-resolution DNS data and preserving the physical characteristics of flow
transport.
Related papers
- Fourier neural operators for spatiotemporal dynamics in two-dimensional turbulence [3.0954913678141627]
We identify that the Fourier neural operator (FNO) based models combined with a partial differential equation (PDE) solver can accelerate fluid dynamic simulations.
We also discuss the pitfalls of purely data-driven approaches that need to be avoided by the machine learning models to become viable and competitive tools for long time simulations of turbulence.
arXiv Detail & Related papers (2024-09-23T02:02:02Z) - Physics-enhanced Neural Operator for Simulating Turbulent Transport [9.923888452768919]
This paper presents a physics-enhanced neural operator (PENO) that incorporates physical knowledge of partial differential equations (PDEs) to accurately model flow dynamics.
The proposed method is evaluated through its performance on two distinct sets of 3D turbulent flow data.
arXiv Detail & Related papers (2024-05-31T20:05:17Z) - Neural Operators for Accelerating Scientific Simulations and Design [85.89660065887956]
An AI framework, known as Neural Operators, presents a principled framework for learning mappings between functions defined on continuous domains.
Neural Operators can augment or even replace existing simulators in many applications, such as computational fluid dynamics, weather forecasting, and material modeling.
arXiv Detail & Related papers (2023-09-27T00:12:07Z) - Physics-Driven Turbulence Image Restoration with Stochastic Refinement [80.79900297089176]
Image distortion by atmospheric turbulence is a critical problem in long-range optical imaging systems.
Fast and physics-grounded simulation tools have been introduced to help the deep-learning models adapt to real-world turbulence conditions.
This paper proposes the Physics-integrated Restoration Network (PiRN) to help the network to disentangle theity from the degradation and the underlying image.
arXiv Detail & Related papers (2023-07-20T05:49:21Z) - NeuralStagger: Accelerating Physics-constrained Neural PDE Solver with
Spatial-temporal Decomposition [67.46012350241969]
This paper proposes a general acceleration methodology called NeuralStagger.
It decomposing the original learning tasks into several coarser-resolution subtasks.
We demonstrate the successful application of NeuralStagger on 2D and 3D fluid dynamics simulations.
arXiv Detail & Related papers (2023-02-20T19:36:52Z) - Physics-informed Deep Super-resolution for Spatiotemporal Data [18.688475686901082]
Deep learning can be used to augment scientific data based on coarse-grained simulations.
We propose a rich and efficient temporal super-resolution framework inspired by physics-informed learning.
Results demonstrate the superior effectiveness and efficiency of the proposed method compared with baseline algorithms.
arXiv Detail & Related papers (2022-08-02T13:57:35Z) - Machine Learning model for gas-liquid interface reconstruction in CFD
numerical simulations [59.84561168501493]
The volume of fluid (VoF) method is widely used in multi-phase flow simulations to track and locate the interface between two immiscible fluids.
A major bottleneck of the VoF method is the interface reconstruction step due to its high computational cost and low accuracy on unstructured grids.
We propose a machine learning enhanced VoF method based on Graph Neural Networks (GNN) to accelerate the interface reconstruction on general unstructured meshes.
arXiv Detail & Related papers (2022-07-12T17:07:46Z) - Physics Informed RNN-DCT Networks for Time-Dependent Partial
Differential Equations [62.81701992551728]
We present a physics-informed framework for solving time-dependent partial differential equations.
Our model utilizes discrete cosine transforms to encode spatial and recurrent neural networks.
We show experimental results on the Taylor-Green vortex solution to the Navier-Stokes equations.
arXiv Detail & Related papers (2022-02-24T20:46:52Z) - Reconstructing High-resolution Turbulent Flows Using Physics-Guided
Neural Networks [3.9548535445908928]
Direct numerical simulation (DNS) of turbulent flows is computationally expensive and cannot be applied to flows with large Reynolds numbers.
Large eddy simulation (LES) is an alternative that is computationally less demanding, but is unable to capture all of the scales of turbulent transport accurately.
We build a new data-driven methodology based on super-resolution techniques to reconstruct DNS data from LES predictions.
arXiv Detail & Related papers (2021-09-06T03:01:24Z) - Real-time simulation of parameter-dependent fluid flows through deep
learning-based reduced order models [0.2538209532048866]
Reduced order models (ROMs) provide reliable approximations to parameter-dependent fluid dynamics problems in rapid times.
Deep learning (DL)-based ROMs overcome all these limitations by learning in a non-intrusive way both the nonlinear trial manifold and the reduced dynamics.
The resulting POD-DL-ROMs are shown to provide accurate results in almost real-time for the flow around a cylinder benchmark, the fluid-structure interaction between an elastic beam attached to a fixed, rigid block and a laminar incompressible flow, and the blood flow in a cerebral aneurysm.
arXiv Detail & Related papers (2021-06-10T13:07:33Z) - Machine learning for rapid discovery of laminar flow channel wall
modifications that enhance heat transfer [56.34005280792013]
We present a combination of accurate numerical simulations of arbitrary, flat, and non-flat channels and machine learning models predicting drag coefficient and Stanton number.
We show that convolutional neural networks (CNN) can accurately predict the target properties at a fraction of the time of numerical simulations.
arXiv Detail & Related papers (2021-01-19T16:14:02Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.