Abstract
Precise ionospheric total electron content (TEC) is critical for many aerospace applications, and forecasting ionospheric TEC is of great significance to it. Besides, short-term prediction of TEC values fills the gap between the TEC product latency and the precision. The machine learning-based approaches are promising in solving the nonlinear prediction issues, particularly suitable for short-term global positioning system TEC forecasting due to its complex temporal and spatial variation. In this article, four different machine learning models, i.e., artificial neural network, long short-term memory networks, adaptive neuro-fuzzy inference system based on subtractive clustering, and gradient boosting decision tree (GBDT) are applied for forecasting ionospheric TEC in three IGS GNSS monitoring stations at the low-latitude region (16°S to 10°S). The performance of these approaches in extreme conditions is investigated, including the high solar activity and magnetic storm, which are the most challenging scenario for TEC prediction. The results show that the machine learning algorithms outperform the global ionospheric map prediction model. The prediction accuracy during the high solar activity period was improved from 37.93% to 49.28%. During the magnetic storm period, the prediction accuracy was improved from 28.16% to 67.39%. Among the machine learning algorithms, the GBDT model outperforms the rest three algorithms in ionosphere prediction scenarios, which improves the prediction accuracy by 5.6% and 12.7% than the rest three approaches on average during high solar activity (2012–2015) and magnetic storm periods respectively.
Highlights
C ONTINUOUS monitoring of the ionosphere layer has been carried out using many geodesy techniques due to significant effects on both communications and global navigation satellite systems (GNSSs) [1]–[4]
Real-time precise ionosphere total electron content (TEC) monitoring is critical for many aerospace applications, while the classical prediction methods based on time series analysis cannot meet the requirement
The machine learning-based approach can learn the implicit relationship between the ionosphere TEC value and the external features, which can be used to improve the precision of short-term ionosphere TEC prediction
Summary
C ONTINUOUS monitoring of the ionosphere layer has been carried out using many geodesy techniques due to significant effects on both communications and global navigation satellite systems (GNSSs) [1]–[4]. A few machine learning approaches have been used in the ionosphere prediction, such as the standard neural network (NN) approach [14]–[16], long short-term memory (LSTM) [17]–[19], adaptive neuro-fuzzy inference system (ANFIS) [20], etc Their performance has been evaluated and has been compared with the GIM and IRI-2016 models and the results show that these machine learning algorithms outperform the existing models. The phase smoothing pseudorange method is the most widely used method, which is used to generate the global ionospheric map product; we adopt this method to estimate the STEC This STEC can be derived from the following equation: P4 = P1 − P2. The testing dataset is used to evaluate the predicting capacity of these models
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