Physics guided wavelet convolutional neural network for wind-induced vibration modeling with application to structural dynamic reliability analysis

•The physics guided wavelet convolutional neural network (PGwCNN) is proposed to predict the structural wind-induced response.•The law of dynamics, is embedded in the wCNN to inform the learning and constrain the training to a feasible space.•A framework of efficient reliability analysis using the p...

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Bibliographic Details
Published in:Engineering structures 2023-12, Vol.297, p.117027, Article 117027
Main Authors: Xu, Zidong, Wang, Hao, Xing, Chenxi, Tao, Tianyou, Mao, Jianxiao, Liu, Yun
Format: Article
Language:English
Subjects:
Deeping learning
Physics guided wavelet convolutional neural network
Probability density evolution method
Surrogate modelling
Wind turbine tower
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Summary:•The physics guided wavelet convolutional neural network (PGwCNN) is proposed to predict the structural wind-induced response.•The law of dynamics, is embedded in the wCNN to inform the learning and constrain the training to a feasible space.•A framework of efficient reliability analysis using the proposed method is introduced.•The dynamic reliability analysis of a high and flexible wind turbine tower was conducted. Deep neural network (NN) has become one of the common choices of surrogate model for reliability analysis of structural dynamic response under complex wind loads. However, the cost of data acquisition is usually prohibitive, making it hard for NN training to accurately replace the complex wind-structure coupled system using the limited data. In this work, a physics guided wavelet convolutional NN (PGwCNN) is regarded as surrogate model of a wind turbine tower (WinTT) and utilized for wind effects prediction. The law of dynamics is regarded as the prior knowledge and encoded in the NN, which can enhance the learning capability of the trained model. Then, the performance of the PGwCNN is demonstrated through the dynamic reliability analysis of a high and flexible WinTT using probability density evolution method (PDEM). What’s more, the L2 regularization and dropout layers are utilized to alleviate the overfitting issues. N-fold cross validation and grid search method are adopted to maximize the use of the limited training datasets. Results demonstrate that PGwCNN is capable to reach a compromise between efficiency and accuracy for predicting wind effects on the WinTT. In addition, the PGwCNN can effectively enhance the calculation efficiency of the reliability analysis.
ISSN:0141-0296
DOI:10.1016/j.engstruct.2023.117027