Abstract
In the meteorology of Global Navigation Satellite System, the weighted mean temperature (Tm) is a key parameter in the process of converting the zenith wetness delay into precipitable water vapor, and it plays an important role in water vapor monitoring. In this research, two deep learning algorithms, namely, recurrent neural network (RNN) and long short-term memory neural network (LSTM), were used to build a high-precision weighted mean temperature model for China using their excellent time series memory capability. The model needs site location information and measured surface temperature to predict the weighted mean temperature. We used data from 118 stations in and around China provided by the Integrated Global Radiosonde Archive from 2010 to 2015 to train the model and data from 2016 for model testing. The root mean square error (RMSE) of the RNN_Tm and LSTM_Tm models were 3.01 K and 2.89 K, respectively. Compared with the values calculated by the empirical GPT3 model, the accuracy was improved by 31.1% (RNN_Tm) and 33.9% (LSTM_Tm). In addition, we selected another 10 evenly distributed stations in China and used the constructed model to test the prediction capability of the weighted mean temperature from 2010 to 2016. The RMSE values were 2.95 K and 2.86 K, which proved that the model also exhibits high generalization in non-modeling sites in China. In general, the RNN_Tm and LSTM_Tm models have a good performance in weighted mean temperature prediction.
Highlights
The deep learning methods recurrent neural network (RNN) and long short-term memory neural network (LSTM) were used to build two models using the data set of 118 sounding stations provided by the Integrated Global Radiosonde Archive (IGRA)
Compared with the global pressure and temperature 3 (GPT3) model, the root mean square error (RMSE) values of the RNN_Tm and LSTM_Tm models were reduced by 31.1% and 33.9%, respectively
Both deep learning methods greatly reduced the RMSE of the model
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. In [21], an improved atmospheric Tm modeling method that uses sparse kernel learning to obtain high-precision and high-time resolution Tm data was proposed. Machine learning algorithm has excellent modeling ability, so it has many applications in hydrology and estimating climate parameters, such as soil moisture, wind speed, temperature, precipitation, water flow and so on. The main modeling idea of this paper is the consideration of the space-time information, temperature, and prior value provided by the GP3 model as the input and the high-precision Tm value obtained by the layered integration of radiosonde data as the output to simulate complex nonlinear relationships and obtain high-precision Tm prediction values.
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