W. Treder, K. Klamkowski, Katarzyna Wójcik, A. Tryngiel-Gać
{"title":"Evapotranspiration Estimation Using Machine Learning Methods","authors":"W. Treder, K. Klamkowski, Katarzyna Wójcik, A. Tryngiel-Gać","doi":"10.2478/johr-2023-0033","DOIUrl":null,"url":null,"abstract":"Abstract The study examined the performance of four machine learning algorithms (regression trees, boosted trees, random forests, and artificial neural networks) for estimating evapotranspiration (ETo) based on incomplete meteorological data. Meteorological variables (mean and maximum air temperature, average air humidity, average level of solar radiation, vapor pressure deficit, extraterrestrial solar radiation, and day number of the year) were used as input. The simulation used two calculation scenarios: data with and without average solar radiation. The performance of the different machine learning models was evaluated using the mean square error, root mean square error, coefficient of determination, and slope of regression forced through the origin between the measured and simulated ETo. The results demonstrated that the applied models were able to describe nonlinear relationships between weather parameters and evapotranspiration. The accuracy of evapotranspiration estimation depended on the type of input variables and the machine learning model used. The highest level of evapotranspiration prediction was obtained using the artificial neural networks model. Including solar radiation data in the calculations improved the quality of evapotranspiration prediction in all four models. In the absence of data on the actual solar radiation reaching the Earth's surface, it is advisable to supplement the input data with data on extraterrestrial solar radiation and the day number of the year. Such an approach can be helpful in areas and situations with limited access to meteorological data.","PeriodicalId":16065,"journal":{"name":"Journal of Horticultural Research","volume":"29 18","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Horticultural Research","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.2478/johr-2023-0033","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Agricultural and Biological Sciences","Score":null,"Total":0}
引用次数: 0
Abstract
Abstract The study examined the performance of four machine learning algorithms (regression trees, boosted trees, random forests, and artificial neural networks) for estimating evapotranspiration (ETo) based on incomplete meteorological data. Meteorological variables (mean and maximum air temperature, average air humidity, average level of solar radiation, vapor pressure deficit, extraterrestrial solar radiation, and day number of the year) were used as input. The simulation used two calculation scenarios: data with and without average solar radiation. The performance of the different machine learning models was evaluated using the mean square error, root mean square error, coefficient of determination, and slope of regression forced through the origin between the measured and simulated ETo. The results demonstrated that the applied models were able to describe nonlinear relationships between weather parameters and evapotranspiration. The accuracy of evapotranspiration estimation depended on the type of input variables and the machine learning model used. The highest level of evapotranspiration prediction was obtained using the artificial neural networks model. Including solar radiation data in the calculations improved the quality of evapotranspiration prediction in all four models. In the absence of data on the actual solar radiation reaching the Earth's surface, it is advisable to supplement the input data with data on extraterrestrial solar radiation and the day number of the year. Such an approach can be helpful in areas and situations with limited access to meteorological data.
摘要 该研究考察了四种机器学习算法(回归树、提升树、随机森林和人工神经网络)在基于不完整气象数据估算蒸散量(ETo)方面的性能。气象变量(平均气温和最高气温、平均空气湿度、平均太阳辐射量、蒸气压差、地外太阳辐射量和年日数)被用作输入。模拟使用了两种计算方案:有平均太阳辐射和无平均太阳辐射的数据。使用测量 ETo 和模拟 ETo 之间的均方误差、均方根误差、判定系数和通过原点的回归斜率评估了不同机器学习模型的性能。结果表明,所应用的模型能够描述天气参数与蒸散量之间的非线性关系。蒸散估计的准确性取决于输入变量的类型和所使用的机器学习模型。人工神经网络模型的蒸散量预测水平最高。将太阳辐射数据纳入计算可提高所有四种模型的蒸散预测质量。在缺乏到达地球表面的实际太阳辐射数据的情况下,最好用地外太阳辐射数据和全年日数数据来补充输入数据。这种方法对于气象数据有限的地区和情况很有帮助。