Abstract
Abstract. This paper proposes a model suitable for predicting the ionosphere delay at different locations of receiver stations using a temporal 1D convolutional neural network (CNN) model. CNN model can optimally addresses non-linearity and model complex data through the creation of powerful representations at hierarchical levels of abstraction. To be able to predict ionosphere values for each visible satellite at a given station, sequence-to-sequence (seq2seq) models are introduced. These models are commonly used for solving sequential problems. In seq2seq models, a sequential input is entered to the model and the output has also a sequential form. Adopting this structure help us to predict ionosphere values for all satellites in view at every epoch. As experimental data, we used global navigation satellite system (GNSS) observations from selected sites in central Europe, of the global international GNSS network (IGS). The data used are part of the multi GNSS experiment (MGEX) project, that provides observations from multiple navigation satellite systems. After processing with precise point positioning (PPP) technique as implemented with GAMP software, the slant total electron content data (STEC) were obtained. The proposed CNN uses as input the ionosphere pierce points (IPP) points coordinates per visible satellite. Then, based on outcomes of the ionosphere parameters, the temporal CNN is deployed to predict future TEC variations.
Highlights
Ionosphere variability is an intense and spatio-temporal varying phenomenon
Applying external ionospheric information would be useful in a precise point positioning-real time kinematic (PPPRTK) processing scenario to enhance the integer ambiguity resolution (IAR) (Psychas et al, 2018) and improve both the performance and convergence time (Aggrey, Bisnath, 2019)
The experimental setup consists of a selected small group of permanent global navigation satellite system (GNSS) stations of the global network of International GNSS Service (IGS)
Summary
Ionosphere variability is an intense and spatio-temporal varying phenomenon. Each global navigation satellite system (GNSS) signal is affected by the ionospheric variability in a different way, depending on signal’s frequency (Hoque, Jakowski, 2007). 1D CNNs have recently been proposed and immediately achieved the state-of-the-art performance levels in various application domains such as detection early diagnosis in medical applications (Kiranyaz et al, 2019), anomaly detection, structural health monitoring and identification in power electronics and energy related applications (Kaselimi et al, 2019). They have simple and compact configuration, as they perform 1D convolutions, they are excellent solution for real-time and low-cost applications
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