A proposed neural network model for obtaining precipitable water vapor

IF 1.2 Q4 REMOTE SENSING Journal of Applied Geodesy Pub Date : 2023-09-14 DOI:10.1515/jag-2023-0035
Hadeer Al-Eshmawy, Mohamed A. Abdelfatah, Gamal S. El-Fiky
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Abstract

Abstract The atmospheric Precipitable water vapor (PWV) is a variable key for weather forecasting and climate change. It is a considerable component of the atmosphere, influencing numerous atmospheric processes, and having physical characteristics. It can be measured directly using radiosonde stations (RS), which are not always accessible and difficult to measure with acceptable spatial and time precision. This study uses the artificial neural network (ANN) application to propose a simple model based on RS data to estimate PWV from surface metrological data. Ten RS stations were used to develop the new model for eight and a half years. In addition, two and a half years of data were used to validate the developed model. The study period is based on the data accessible between 2010 and 2020. The new model needs to collect (vapor pressure, temperature, latitude, longitude, height, day of year, and relative humidity) as input parameters in ANN to predict the PWV. The ANN model validations were based on the root mean square (RMS), correlation coefficient (CC), and T-test. According to the results, the proposed ANN can accurately predict the PWV over Egypt. The results of the new ANN model and eight other empirical models (Saastamoinen, Askne and Nordius, Okulov et al., Maghrabi et al., Phokate., Falaiye et al. (A&B), Qian et al. and ERA 5) are compared in addition, the new PWV model can achieve the best performance with RMS of 0.21 mm. The new model can serve as a will be of practical utility with a high degree of precision in PWV estimation.
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提出了一种获取可降水量的神经网络模型
大气可降水量(PWV)是天气预报和气候变化的变量关键。它是大气的重要组成部分,影响许多大气过程,并具有物理特性。它可以直接使用无线电探空站(RS)进行测量,这些探空站并不总是可以到达并且难以以可接受的空间和时间精度进行测量。本研究利用人工神经网络(ANN)的应用,提出了一种基于遥感数据的地面测量数据估算PWV的简单模型。10个RS站用了8年半的时间来开发新模型。此外,两年半的数据被用来验证所开发的模型。研究期间基于2010年至2020年之间可获得的数据。新模型需要在人工神经网络中收集(蒸汽压、温度、纬度、经度、高度、年份和相对湿度)作为输入参数来预测PWV。基于均方根(RMS)、相关系数(CC)和t检验对人工神经网络模型进行验证。结果表明,所提出的人工神经网络能够准确预测埃及上空的PWV。新的人工神经网络模型和其他八个经验模型(Saastamoinen, Askne和Nordius, Okulov等人,Maghrabi等人,Phokate。与faraiye et al. (A&B), Qian et al.和ERA 5进行了比较,并且新PWV模型的RMS为0.21 mm,可以达到最佳性能。该模型可作为一种实用的模型,在PWV估计中具有较高的精度。
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来源期刊
Journal of Applied Geodesy
Journal of Applied Geodesy REMOTE SENSING-
CiteScore
2.30
自引率
7.10%
发文量
30
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