Model Order Reduction with Neural Networks: Application to Laminar and Turbulent Flows

Model Order Reduction with Neural Networks: Application to Laminar and Turbulent Flows

We investigate the capability of neural network-based model order reduction, i.e., autoencoder (AE), for fluid flows. As an example model, an AE which comprises of convolutional neural networks and multi-layer perceptrons is considered in this study. The AE model is assessed with four canonical flui...

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Veröffentlicht in:SN computer science 2021-11, Vol.2 (6), p.467, Article 467
Hauptverfasser: Fukami, Kai, Hasegawa, Kazuto, Nakamura, Taichi, Morimoto, Masaki, Fukagata, Koji
Format: Artikel
Sprache:eng
Schlagworte:
Artificial neural networks
Channel flow
Computer Imaging
Computer Science
Computer Systems Organization and Communication Networks
Data Structures and Information Theory
Dynamical systems
Fluid dynamics
Fluid flow
Information Systems and Communication Service
Laminar flow
Machine learning
Methods
Model reduction
Multilayer perceptrons
Multilayers
Neural networks
Original Research
Parameter sensitivity
Pattern Recognition and Graphics
Reynolds number
Sea surface temperature
Software Engineering/Programming and Operating Systems
Turbulent flow
Two dimensional flow
Vision
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Zusammenfassung:We investigate the capability of neural network-based model order reduction, i.e., autoencoder (AE), for fluid flows. As an example model, an AE which comprises of convolutional neural networks and multi-layer perceptrons is considered in this study. The AE model is assessed with four canonical fluid flows, namely: (1) two-dimensional cylinder wake, (2) its transient process, (3) NOAA sea surface temperature, and (4) a cross-sectional field of turbulent channel flow, in terms of a number of latent modes, the choice of nonlinear activation functions, and the number of weights contained in the AE model. We find that the AE models are sensitive to the choice of the aforementioned parameters depending on the target flows. Finally, we foresee the extensional applications and perspectives of machine learning based order reduction for numerical and experimental studies in the fluid dynamics community.
ISSN:2662-995X
2661-8907
DOI:10.1007/s42979-021-00867-3