Fast Prediction of Flow Field around Airfoils Based on Deep Convolutional Neural Network

Wu, Mingyu; Wu, Yan; Yuan, Xin-Yi; Chen, Zhihua; Wu, Wei‐Tao; Aubry, Nadine

doi:10.3390/app122312075

Cited by 19 publications

(4 citation statements)

References 50 publications

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“…Depending on the manners by which the ML approaches are integrated with CFD solvers, ML approaches for fluid mechanics can be roughly categorized into three classes, i.e., data-fit models, projection-based models and physics-informed models. A data-fit model is usually based on the artificial neural network (ANN) [5,6], radial basis function (RBF) [7] and support vector regression (SVR) [8,9], and it treats a CFD solver as a black box and is essentially a fast, inexpensive but approximate model that extracts mechanisms underlying the complex system from available data in a supervised manner. Data-fit models have been widely used as a substitute for expensive CFD simulations in design optimization or uncertainty quantification of fluid systems [10].…”

Section: Introductionmentioning

confidence: 99%

On the Hard Boundary Constraint Method for Fluid Flow Prediction based on the Physics-Informed Neural Network

Xiao,

Ju,

et al. 2024

Applied Sciences

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With the rapid development of artificial intelligence technology, the physics-informed neural network (PINN) has gradually emerged as an effective and potential method for solving N-S equations. The treatment of constraints is vital to the PINN prediction accuracy. Compared to soft constraints, hard constraints are advantageous for the avoidance of difficulties in guaranteeing definite conditions and determining penalty coefficients. However, the principles on the formulation of hard constraints of PINN currently remain to be formed, which hinders the application of PINN in engineering fields. In this study, hard-constraint-based PINN models are constructed for Couette flow, plate shear flow and stenotic/aneurysmal flow with curved geometries. Particular efforts have been devoted to assessing the impact of the model parameters of hard constraints, i.e., degree and scaling factor, on the prediction accuracy of PINN at different Reynolds numbers. The results show that the degree is the most important factor that influences the prediction accuracy, followed by the scaling factor. As for the N-S equations, the degree of hard constraints should be at least two, while the scaling factor is recommended to be maintained around 1.0. The outcomes of the present work are of reference value for the development of PINN methods in fluid mechanics.

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Section: Introductionmentioning

confidence: 99%

On the Hard Boundary Constraint Method for Fluid Flow Prediction based on the Physics-Informed Neural Network

Xiao,

Ju,

et al. 2024

Applied Sciences

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“…The proposed model achieved a mean squared error of less than 2% for test cases. Wu et al [21] proposed a CNN-DCNN model, tested the influence of training parameters, and quantified the feature extraction capabilities of the presented model. Despite CNN demonstrating excellent predictive performance, precision, and the ability to capture inherent flow characteristics, particularly in the context of airfoil flow-field prediction, the capability of CNN in handling unstructured flow-field data remains suboptimal, particularly in practical applications with irregular flow path structure [22,23].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Transonic Flow over Cascades via Graph Embedding Methods on Large-Scale Point Clouds

Lan,

Wang,

Wang

et al. 2023

Aerospace

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In this research, we introduce a deep-learning-based framework designed for the prediction of transonic flow through a linear cascade utilizing large-scale point-cloud data. In our experimental cases, the predictions demonstrate a nearly four-fold speed improvement compared to traditional CFD calculations while maintaining a commendable level of accuracy. Taking advantage of a multilayer graph structure, the framework can extract both global and local information from the cascade flow field simultaneously and present prediction over unstructured data. In line with the results obtained from the test datasets, we conducted an in-depth analysis of the geometric attributes of the cascades reconstructed using our framework, considering adjustments made to the geometric information of the point cloud. We fine-tuned the input using 1603 data points and quantified the contribution of each point. The outcomes reveal that variations in the suction side of the cascade have a significantly more substantial influence on the field results compared to the pressure side and explain the way graph neural networks work for cascade flow-field prediction, enhancing the comprehension of graph-based flow-field prediction among developers and proves the potential of graph neural networks in flow-field prediction on large-scale point clouds and design.

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“…However, these simulations can easily become very computationally intensive. In an attempt to reduce the computational burden of CFD simulations, several Reduced Order Models (ROM) have been developed, but these lack good generalization capabilities and struggle when dealing with dynamic, non-linear, aerodynamic phenomena [4,5].…”

Section: Introductionmentioning

confidence: 99%

“…Also, once trained, they are able to produce accurate predictions very quickly [6]. Examples of such applications include the works of Zhang et al [4], Peng et al [7], Wu et al [5], Balla et al [6], and Moin et al [1].…”

Section: Introductionmentioning

confidence: 99%

Fast Flapping Aerodynamics Prediction Using a Recurrent Neural Network

Pereira,

Camacho,

Marques

et al. 2023

The 4th International Electronic Conference on Applied Sciences

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Fast Prediction of Flow Field around Airfoils Based on Deep Convolutional Neural Network

Cited by 19 publications

References 50 publications

On the Hard Boundary Constraint Method for Fluid Flow Prediction based on the Physics-Informed Neural Network

On the Hard Boundary Constraint Method for Fluid Flow Prediction based on the Physics-Informed Neural Network

Prediction of Transonic Flow over Cascades via Graph Embedding Methods on Large-Scale Point Clouds

Fast Flapping Aerodynamics Prediction Using a Recurrent Neural Network

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