2022
DOI: 10.1063/5.0082741
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Three-dimensional deep learning-based reduced order model for unsteady flow dynamics with variable Reynolds number

Abstract: In this article, we present a deep learning-based reduced order model (DL-ROM) for predicting the fluid forces and unsteady vortex shedding patterns. We consider the flow past a sphere to examine the accuracy of our DL-ROM predictions. The proposed DL-ROM methodology relies on a three-dimensional convolutional recurrent autoencoder network (3D CRAN) to extract the low-dimensional flow features from the full-order snapshots in an unsupervised manner. The low-dimensional features are evolved in time using a long… Show more

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Cited by 40 publications
(11 citation statements)
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“…The data-driven methods of modal decomposition approaches called proper orthogonal decomposition (POD) and dynamic mode decomposition (DMD) are becoming more and more popular recently to provide physical insights into the cavitation instabilities (Gupta & Jaiman, 2022; Liu, Long, Wu, Huang, & Wang, 2021) instead of observing the evolution of cavity on acquired high-speed images, to explore these abundant spatial-temporal features of coherent structures and the associated dynamics in cavitation flows, especially in the sheet/cloud cavitation regime. For example, Prothin, Billard, and Djeridi (2016) experimentally investigated the sheet/cloud cavitation instabilities around a NACA0015 foil at high Reynolds number using POD and DMD, and pointed out the occurrence of three-dimensional (3-D) effects due to the re-entrant jet instabilities or due to the propagating shockwave mechanism at the origin of the shedding process of the cavitation cloud.…”
Section: Introductionmentioning
confidence: 99%
“…The data-driven methods of modal decomposition approaches called proper orthogonal decomposition (POD) and dynamic mode decomposition (DMD) are becoming more and more popular recently to provide physical insights into the cavitation instabilities (Gupta & Jaiman, 2022; Liu, Long, Wu, Huang, & Wang, 2021) instead of observing the evolution of cavity on acquired high-speed images, to explore these abundant spatial-temporal features of coherent structures and the associated dynamics in cavitation flows, especially in the sheet/cloud cavitation regime. For example, Prothin, Billard, and Djeridi (2016) experimentally investigated the sheet/cloud cavitation instabilities around a NACA0015 foil at high Reynolds number using POD and DMD, and pointed out the occurrence of three-dimensional (3-D) effects due to the re-entrant jet instabilities or due to the propagating shockwave mechanism at the origin of the shedding process of the cavitation cloud.…”
Section: Introductionmentioning
confidence: 99%
“…Regarding IROMs, the exact form of the underlying partial differential equations (PDEs) is essential to generate simplified models from high fidelity snapshots [27], in an ordered database called snapshot matrix [28]. Proper orthogonal decomposition (POD) approximates the intrinsic dimensions of the HFM solutions by utilizing linear algebra techniques such as principal component analysis, and singular value decomposition (SVD) [29,30].…”
Section: Introductionmentioning
confidence: 99%
“…In recent years, NIROMs DL-based have been the subject of several studies aiming to overcome the limitations of the linear projections methods [28], by recovering non-linear, low-dimensional manifolds [36,42]. Various methodologies have been proposed, including supervised and unsupervised DL techniques, to identify low-dimensional manifolds and nonlinear dynamic behaviors [49].…”
Section: Introductionmentioning
confidence: 99%
“…In recent years, machine learning has witnessed a resurgence owing primarily to the enormous success of deep learning models in a wide range of applications 22 . One such application is reduced-order modeling, in which a deep learning model is used as a black box technique to approximate a physical system 9,14 . Deep neural networks, one of the most popular deep learning models, have proven to be an effective method for modeling physical systems, e.g.…”
Section: Introductionmentioning
confidence: 99%
“…Explicit physical constraints in the loss function necessitate numerical solution of a partial differential equation which brings back the computational infeasibility of numerical methods 21,36 . In recent body of works 9,14,27 , deep neural networks have been shown to model complex fluid-structure interaction and wave propagation phenomenon without relying on explicit physical constraints or inductive biases in the loss function. Convolutional recurrent autoencoder network (CRAN) 3,4,8 , is a deep neural network that can be effective for data-driven model reduction and learning of nonlinear partial differential equations.…”
Section: Introductionmentioning
confidence: 99%