Water deep mapping from HJ-1B satellite data by a deep network model in the sea area of Pearl River Estuary, China

Remote sensing (RS) water depth inversion is an important technology and the method of water depth measurement. Taking the waters around the islands outside the Pearl River Estuary as an example, five optical RS depth inversion algorithms were introduced. Then, five water depth inversion models were...

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Autores principales: Zhao Xiaoning, Wang Daqing, Xu Haoli, Shi Yue, Deng Zhengdong, Ding Zhibin, Liu Zhixin, Xu Xingang, Lu Zhao, Wang Guangyuan, Cheng Zijian
Formato: article
Lenguaje:EN
Publicado: De Gruyter 2021
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rs
Acceso en línea:https://doaj.org/article/37b39c4ab9414fe2b9abd99e780a0c61
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Sumario:Remote sensing (RS) water depth inversion is an important technology and the method of water depth measurement. Taking the waters around the islands outside the Pearl River Estuary as an example, five optical RS depth inversion algorithms were introduced. Then, five water depth inversion models were trained through the HJ-1B satellite RS image and the measured water depth data. The results show that the mean absolute error (MAE) of the deep learning model was the smallest (2.350 m), and that the distribution of predicted water depth points was closest to the actual value. Deep learning has been widely used in RS image classification and recognition and shows its advantages. Therefore, the deep learning model was applied to extract the depth of the shallow water. Meanwhile, the obtained inversion effect map is closest to the actual contour map. The water depth inversion performance of back propagation neural network model is better than that of the radial basis function (RBF) neural network model. Besides, the inversion accuracy of the RBF neural network may be affected due to the small amount of data and the improper number of hidden neurons. The results show broad application prospects of machine learning algorithms in RS water depth inversion. Also, this study provided data support for model optimization, training, and parameter setting.