基于监督机器学习模型的气象变量土壤湿度估计

M. Hussain, N. Sharmin, Sumayea Binte Shafiul
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引用次数: 0

摘要

水循环、气候相关灾害和农业灌溉都受到土壤水分含量的强烈控制。对于水资源管理而言,预测是减轻和调节预期经济损失和财产损失的关键。本文比较了两种监督机器学习(ML)技术:支持向量回归(SVR)和随机森林(RF)来预测SM。在RStudio中,各种气象变量:温度、相对湿度、风速和降雨量被训练来估计SM。对于8个部门,SM和天气变量来自美国国家航空航天局(NASA)的全球能源预测(POWER)。实验包括39年(1982年至2020年)的日常观测,以建立SVR和RF模型。为了从预测模型中估计SM,来自不同地区的数据集:Rajshahi, Mymensingh,吉大港和Sylhet被用于训练(60%),Rangpur, Barisal, Khulna和Dhaka被分离用于验证(40%),准确度为88至95.8%。该模型进一步应用于预测每个城市(包括两个地区(Bogra和Jessore))的每日SM,发现SVR(90.7%)的模型性能略高于RF(90.1%)的平均水平(年份:2021)。对于农业、工业和城市供水以及干旱、滑坡和河流侵蚀,可以通过准确估计土壤湿度来减轻。本研究鼓励在数据稀疏的地区,通过有监督的ML技术向公众提供SM预算。
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Estimation of Soil Moisture with Meteorological Variables in Supervised Machine Learning Models
Water cycles, climate-related hazards, and agroirrigation are strongly controlled by soil moisture (SM) content. For water resource management, prediction is a key to mitigate and regulate expected economic losses and property damages. This paper compares two supervised machine learning (ML) techniques: support vector regression (SVR) and random forest (RF) to predict SM. In RStudio, various meteorological variables: temperature, relative humidity, wind speed, and rainfall are trained to estimate SM. For eight divisions, SM and weather variables are obtained from the National Aeronautics and Space Administration (NASA) Prediction of Worldwide Energy Resources (POWER). The experiments include daily observations for 39 (1982 to 2020) to develop SVR and RF models. To estimate SM from the predictive model, datasets from diverse regions: Rajshahi, Mymensingh, Chittagong, and Sylhet are utilized in training (60%) and Rangpur, Barisal, Khulna, and Dhaka are segregated for validation (40%) resulting in accuracy of 88 to 95.8%. This model further is applied to forecast daily SM for each city including two districts (Bogra and Jessore) and found slightly higher model performance for SVR (90.7%) than RF (90.1%) on average (Year: 2021). For agricultural, industrial and urban water supplies as well as drought, landslides, and river erosions can be mitigated by an accurate estimation of soil moisture. The investigations encourage for providing SM budget to public with supervised ML techniques mostly among data-sparse regions.
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