Significant Wave Height Prediction based on Wavelet Graph Neural Network
- URL: http://arxiv.org/abs/2107.09483v1
- Date: Tue, 20 Jul 2021 13:34:48 GMT
- Title: Significant Wave Height Prediction based on Wavelet Graph Neural Network
- Authors: Delong Chen, Fan Liu, Zheqi Zhang, Xiaomin Lu, Zewen Li
- Abstract summary: "Soft computing" approaches, including machine learning and deep learning models, have shown numerous success in recent years.
A Wavelet Graph Neural Network (WGNN) approach is proposed to integrate the advantages of wavelet transform and graph neural network.
Experimental results show that the proposed WGNN approach outperforms other models, including the numerical models, the machine learning models, and several deep learning models.
- Score: 2.8383948890824913
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Computational intelligence-based ocean characteristics forecasting
applications, such as Significant Wave Height (SWH) prediction, are crucial for
avoiding social and economic loss in coastal cities. Compared to the
traditional empirical-based or numerical-based forecasting models, "soft
computing" approaches, including machine learning and deep learning models,
have shown numerous success in recent years. In this paper, we focus on
enabling the deep learning model to learn both short-term and long-term
spatial-temporal dependencies for SWH prediction. A Wavelet Graph Neural
Network (WGNN) approach is proposed to integrate the advantages of wavelet
transform and graph neural network. Several parallel graph neural networks are
separately trained on wavelet decomposed data, and the reconstruction of each
model's prediction forms the final SWH prediction. Experimental results show
that the proposed WGNN approach outperforms other models, including the
numerical models, the machine learning models, and several deep learning
models.
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