Deep Convolutional Recurrent Autoencoders for Flow Field Prediction

In this paper, an end-to-end nonlinear model reduction methodology is presented based on the convolutional recurrent autoencoder networks. The methodology is developed in the context of the overall data-driven reduced-order model framework proposed in the paper. The basic idea behind the methodology...

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Bibliographic Details
Published inarXiv.org
Main Authors Sandeep Reddy Bukka, Allan Ross Magee, Jaiman, Rajeev Kumar
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 22.03.2020
Subjects
Artificial neural networks
Bluff bodies
Cylinders
Errors
Methodology
Model reduction
Neural networks
Recurrent neural networks
Reduced order models
Representations
Unsteady flow
Velocity distribution
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Summary:In this paper, an end-to-end nonlinear model reduction methodology is presented based on the convolutional recurrent autoencoder networks. The methodology is developed in the context of the overall data-driven reduced-order model framework proposed in the paper. The basic idea behind the methodology is to obtain the low dimensional representations via convolutional neural networks and evolve these low dimensional features via recurrent neural networks in the time domain. The high dimensional representations are constructed from the evolved low dimensional features via transpose convolutional neural networks. With an unsupervised training strategy, the model serves as an end to end tool which can evolve the flow state of the nonlinear dynamical system. The convolutional recurrent autoencoder network model is applied to the problem of flow past bluff bodies for the first time. To demonstrate the effectiveness of the methodology, two canonical problems namely the flow past a plain cylinder and the flow past side-by-side cylinders are explored in this paper. Pressure and velocity fields of the unsteady flow are predicted in future via the convolutional recurrent autoencoder model. The performance of the model is satisfactory for both the problems. Specifically, the multiscale nature and the gap flow dynamics of the side-by-side cylinders are captured by the proposed data-driven model reduction methodology. The error metrics, the normalized squared error, and the normalized reconstruction error are considered for the assessment of the data-driven framework.
ISSN:2331-8422