Shallow Water Bathymetry Retrieval by Optical Remote Sensing Based on Depth-Invariant Index and Location Features

IF 2 4区地球科学 Q3 REMOTE SENSING Canadian Journal of Remote Sensing Pub Date : 2022-07-04 DOI:10.1080/07038992.2022.2104235

Jinshan Zhu, Fei Yin, Jian Qin, Jiawei Qi, Zhaoyu Ren, Peng Hu, Jingyu Zhang, Xueqing Zhang, Ruifu Wang

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引用次数: 2

Abstract

Abstract At present, most machine learning bathymetry retrieval models use the band reflectance as the inversion feature only, without considering features related to the water substrate and pixel spatial correlation. In this study, in addition to band reflectance, two features, Depth-Invariant Index (DII) and pixel location, are taken into account. Two machine learning algorithms, Random Forest (RF) and Back Propagation (BP) neural network are used to retrieve bathymetry. The effects of the two features on the accuracy and performance of bathymetry retrieval are explored. The results show that: (i) Machine learning algorithms are generally superior to the widely used Stumpf model. Stumpf model performs better only in the depth range of 8–16 m, with a Root Mean Square Error (RMSE) of 0.85 m, but has poor performance in other depth ranges. (ii) Compared with models that use Band Reflectance (BR) only, DIIb,g (blue-green DII) + BR model, Location and Location + BR models are all superior to the BR model for RF and BP algorithms. It means that DII and location features are very effective in improving the bathymetry retrieval accuracy.

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基于深度不变指数和位置特征的光学遥感浅水水深反演

目前，大多数机器学习测深检索模型只使用波段反射率作为反演特征，而没有考虑与水体基质相关的特征和像元空间相关性。在本研究中，除了波段反射率外，还考虑了两个特征，深度不变指数(deep - invariant Index, DII)和像素位置。使用随机森林(RF)和反向传播(BP)神经网络两种机器学习算法来检索水深。探讨了这两个特征对水深反演精度和性能的影响。结果表明:(1)机器学习算法总体上优于广泛使用的Stumpf模型。Stumpf模型仅在8-16 m深度范围内表现较好，均方根误差(RMSE)为0.85 m，而在其他深度范围内表现较差。(ii)与仅使用Band Reflectance (BR)的模型相比，DIIb、g(蓝绿DII) + BR模型、Location和Location + BR模型对于RF和BP算法均优于BR模型。这意味着DII和位置特征在提高测深反演精度方面是非常有效的。

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来源期刊

Canadian Journal of Remote Sensing REMOTE SENSING-

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3.80%

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期刊介绍： Canadian Journal of Remote Sensing / Journal canadien de télédétection is a publication of the Canadian Aeronautics and Space Institute (CASI) and the official journal of the Canadian Remote Sensing Society (CRSS-SCT). Canadian Journal of Remote Sensing provides a forum for the publication of scientific research and review articles. The journal publishes topics including sensor and algorithm development, image processing techniques and advances focused on a wide range of remote sensing applications including, but not restricted to; forestry and agriculture, ecology, hydrology and water resources, oceans and ice, geology, urban, atmosphere, and environmental science. Articles can cover local to global scales and can be directly relevant to the Canadian, or equally important, the international community. The international editorial board provides expertise in a wide range of remote sensing theory and applications.