Can the Soil Erosion in Coastal Mountainous Areas Disturbed by Electric-Transmission-Line Construction be Estimated with a Deep Learning Model?

Q3 Environmental Science Journal of Resources and Ecology Pub Date : 2023-08-22 DOI:10.5814/j.issn.1674-764x.2023.05.013
Li Xi, Shixiong Jiang, Shanshan Zhao, Xiaomei Li, Chen Yao, Chongqing Wang, Sunxian Weng
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Abstract

Abstract: Soil erosion monitoring in coastal mountainous areas is very important during the construction of Electric-Transmission-Line (ETL) because of the impact this disturbance has on the sensitive environment. In this study, high-resolution remote sensing data and deep learning models including Dense and Long Short-Term Memory (LSTM) were used to fit the popular soil erosion equation, which is called the Revised Universal Soil Loss Equation (RUSLE), for the Min-Yue ETL (in Fujian). The accuracy of soil erosion regression was then evaluated in the transmission line buffer area and sampling spots at two spatial scales in order to obtain the optimized parameters and a suitable model. The results show that the Dense and LSTM models can meet the accuracy requirements by using 10 characteristic values, including soil erodibility, annual rainfall, mountain vegetation index (NDMVI), DEM, slope, four bands gray values of high-spectral image, construction attributes. The optimized parameters for the priority machine-learning model LSTM are as follows: the layer depth is 3, the layer capacity is 512, the dropout ratio is 0.1, and the epoch of the LSTM model is 7060. The regression accuracy of the LSTM model decreases with an increase in soil erosion levels, and the average regression accuracy is greater than 0.98 for the slight level of soil erosion. Therefore, the machine-learning model of LSTM can be applied for quickly monitoring the soil erosion using high resolution remote sensing data.
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输电线路建设对沿海山区土壤侵蚀的影响能否用深度学习模型进行估计?
摘要:沿海山区土壤侵蚀监测是输电线路建设过程中的一个重要环节,因为这种扰动会对敏感环境产生影响。在本研究中,使用高分辨率遥感数据和包括密集和长短期记忆(LSTM)在内的深度学习模型来拟合闽粤ETL(福建)的流行土壤侵蚀方程,即修正的通用土壤流失方程(RUSLE)。然后在输电线路缓冲区和两个空间尺度的采样点中评估土壤侵蚀回归的准确性,以获得优化的参数和合适的模型。结果表明,Dense和LSTM模型通过使用土壤可蚀性、年降雨量、山地植被指数(NDMVI)、DEM、坡度、高光谱图像四带灰度值、构造属性等10个特征值,可以满足精度要求。优先级机器学习模型LSTM的优化参数如下:层深度为3,层容量为512,丢弃率为0.1,LSTM模型的历元为7060。LSTM模型的回归精度随着土壤侵蚀程度的增加而降低,对于轻度土壤侵蚀,平均回归精度大于0.98。因此,LSTM的机器学习模型可以应用于利用高分辨率遥感数据快速监测土壤侵蚀。
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来源期刊
Journal of Resources and Ecology
Journal of Resources and Ecology Environmental Science-Ecology
CiteScore
2.40
自引率
0.00%
发文量
107
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