Abstract
Antarctica has a significant impact on global climate change. However, to draw climate change scenarios, there is a need for meteorological data, such as water vapor content, which is scarce in Antarctica. Global navigation satellite system (GNSS) networks can play a major role in overcoming this problem as the tropospheric delay that can be derived from GNSS measurements is an important data source for monitoring the variation of water vapor content. This work intends to be a contribution for improving the estimation of the zenith tropospheric delay (ZTD) obtained with the latest global pressure–temperature (GPT3) model for Antarctica through the use of long short-term-memory (LSTM) and radial basis function (RBF) neural networks for modifying GPT3_ZTD. The forecasting ZTD model is established based on the GNSS_ZTD observations at 71 GNSS stations from 1 January 2018 to 23 October 2021. According to the autocorrelation of the bias series between GNSS_ZTD and GPT3_ZTD, we predict the LSTM_ZTD for each GNSS station for period from October 2020 to October 2021 using the LSTM day by day. Based on the bias between LSTM_ZTD and GPT3_ZTD of the training stations, the RBF is adopted to estimate the LSTM_RBF_ZTD of the verified station, where the LSTM_ZTD represents the temporal forecasting ZTD at a single station, and the LSTM_RBF_ZTD represents the predicted ZTD obtained from space. Both the daily and yearly RMSE are calculated against the reference (GNSS_ZTD), and the improvement of predicted ZTD is compared with GPT3_ZTD. The results show that the single-station LSTM_ZTD series has a good agreement with the GNSS_ZTD, and most daily RMSE values are within 20 mm. The yearly RMSE of the 65 stations ranges from 6.4 mm to 32.8 mm, with an average of 10.9 mm. The overall accuracy of the LSTM_RBF_ZTD is significantly better than that of the GPT3_ZTD, with the daily RMSE of LSTM_RBF_ZTD significantly less than 30 mm, and the yearly RMSE ranging from 5.6 mm to 50.1 mm for the 65 stations. The average yearly RMSE is 15.7 mm, which is 10.2 mm less than that of the GPT3_ZTD. The LSTM_RBF_ZTD of 62 stations is more accurate than GPT3_ZTD, with the maximum improvement reaching 76.3%. The accuracy of LSTM_RBF_ZTD is slightly inferior to GPT3_ZTD at three stations located in East Antarctica with few GNSS stations. The average improvement across the 65 stations is 39.6%.
Highlights
GPT3_ZTD of the training stations, the radial basis function (RBF) is adopted to estimate the LSTM_RBF_ZTD of the verified station, where the LSTM_ZTD represents the temporal forecasting zenith tropospheric delay (ZTD) at a single station, and the LSTM_RBF_ZTD represents the predicted ZTD obtained from space
The results show that the single-station LSTM_ZTD series has a good agreement with the GNSS_ZTD, and most daily root mean square error (RMSE) values are within 20 mm
To overcome the poor performance of the Global Pressure and Temperature (GPT) model in estimating tropospheric delay in Antarctica, here we propose the use of two machine learning methods to improve the GPT3 model and build a forecasting ZTD model in Antarctica
Summary
Monitoring water vapor in Antarctica is of great importance for understanding global precipitation. More than 120 countries and 16 organizations have built observation stations in Antarctica. Due to the limited temporal and spatial resolution of data observed by the meteorological stations, global navigation satellite system (GNSS). Observations are an effective complement for retrieving water vapor with higher temporal resolution. In previous work, based on the GNSS tropospheric delay calculated using a traditional troposphere model and surface-measured meteorological observations, precipitable water vapor (PWV) at Scott Base and McMurdo stations in Antarctica is determined [1].
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