Clock bias prediction algorithm for navigation satellites based on a supervised learning long short-term memory neural network

Huang, Bohua; Ji, Zengxi; Zhai, Renjian; Xiao, Changfu; Yang, Fan; Yang, Bohang; Wang, Yupu

doi:10.1007/s10291-021-01115-0

Cited by 18 publications

(8 citation statements)

References 12 publications

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“…• Gross error removal and interpolation: Serious gross errors will affect the accuracy of clock error forecasting. The Median Absolute Deviation (MAD) can indicate gross errors in the data sequence (Huang et al, 2021a(Huang et al, , 2021b. After all gross errors are removed, the cubic spline interpolation method can be used to smooth fill in missing values.…”

Section: Data Preprocessingmentioning

confidence: 99%

“…Since space-based atomic clocks are disturbed by factors such as mechanical vibration, electromagnetic radiation, and temperature changes, their clock error prediction models also include nonlinear random terms. Many studies have shown that neural network models have better forecasting effects on nonlinear data (Huang et al, 2021a(Huang et al, , 2021b. Among them, the Long Short-Term Memory (LSTM) neural network model exhibits a better forecasting effect on time series data (Greff et al, 2016;Wang et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Long-term autonomous time-keeping of navigation constellations based on sparse sampling LSTM algorithm

Yang,

Yi,

Dong

et al. 2024

Satell Navig

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The system time of the four major navigation satellite systems is mainly maintained by multiple high-performance atomic clocks at ground stations. This operational mode relies heavily on the support of ground stations. To enhance the high-precision autonomous timing capability of next-generation navigation satellites, it is necessary to autonomously generate a comprehensive space-based time scale on orbit and make long-term, high-precision predictions for the clock error of this time scale. In order to solve these two problems, this paper proposed a two-level satellite timing system, and used multiple time-keeping node satellites to generate a more stable space-based time scale. Then this paper used the sparse sampling Long Short-Term Memory (LSTM) algorithm to improve the accuracy of clock error long-term prediction on space-based time scale. After simulation, at sampling times of 300 s, 8.64 × 104 s, and 1 × 106 s, the frequency stabilities of the spaceborne timescale reach 1.35 × 10–15, 3.37 × 10–16, and 2.81 × 10–16, respectively. When applying the improved clock error prediction algorithm, the ten-day prediction error is 3.16 × 10–10 s. Compared with those of the continuous sampling LSTM, Kalman filter, polynomial and quadratic polynomial models, the corresponding prediction accuracies are 1.72, 1.56, 1.83 and 1.36 times greater, respectively.

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Section: Data Preprocessingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Long-term autonomous time-keeping of navigation constellations based on sparse sampling LSTM algorithm

Yang,

Yi,

Dong

et al. 2024

Satell Navig

View full text Add to dashboard Cite

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“…7). The ML models have been compared with several conventional non-ML models: regression model [14,80,101,159,160], brute force approach [143], traditional statistical approaches [60,94,[161][162][163][164], classical KF [129], Bayes-optimal rule [118], least square (LS)-based approach [40], Saastamoinen model [110], autoregressive model and a traditional LEO propagation model (EKF-STAN) [146], conventional wind speed retrieval method [43], Maximum-Likelihood Power-Distortion (PD-ML) [165], BERNESE 5.2 [114], CYGNSS [44], Hydrostaticseasonal-time (HST) model [49], Statistical Theta method [51][52][53]166], MAPGEO2004 geoid model [73], GNSS-IR soil moisture [58], Autoregressive (AR) and Autoregressive Moving Average (ARMA) [167], ERA-Interima global atmospheric reanalysis (now ERA5 reanalysis) [107], Empirical linear algorithms (LRM and LLM) [59], International Reference Ionosphere (IRI) 2016 model [168], NeQuick and IRI-2001 global TEC model [169][170][171], EKF-based integration scheme [172], CODE GIMs (Global Ionospheric Maps) [173], autoregressive integrated moving average (ARIMA), and quadratic polynomial (QP) models [174], least square regression algorithms (LSR) and bi-ha...…”

Section: E ML Vs Non-ml Models (Rq4a)mentioning

confidence: 99%

A Systematic Review of Machine Learning Techniques for GNSS Use Cases

Siemuri

Selvan

Välisuo

et al. 2022

IEEE Trans. Aerosp. Electron. Syst.

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In terms of the availability and accuracy of positioning, navigation, and timing (PNT), the traditional Global Navigation Satellite System (GNSS) algorithms and models perform well under good signal conditions. In order to improve their robustness and performance in less than optimal signal environments, many researchers have proposed machine learning (ML) based GNSS models (ML models) as early as the 1990s. However, no study has been done in a systematic way to analyze the extent of the research on the utilization of ML models in GNSS and their performance. The aim of this research is to perform a systematic review of the type of ML models utilized in GNSS use cases, their performance with respect to accuracy, their comparison with other models (ML and non-ML), and their GNSS application context. In this study, we perform a systematic review of studies from 2000 to 2021 in the literature that utilizes machine learning techniques in GNSS use cases. We assess the performance of the machine learning techniques in the existing literature on their application to GNSS. Furthermore, the strengths and weaknesses of machine learning techniques are summarized. In this paper, we have identified 213 selected studies and ten categories of machine learning techniques. The results prove the acceptable performance of machine learning

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“…Their experimental results suggested that the accuracy and stability of the model were significantly better than those of traditional models such as the quadratic polynomial model and gray model; in particular, the advantage of this model was obvious when forecasting a cesium atomic clock. A further study [ 27 ] proposed a clock bias forecasting model that combined supervised learning and a long short-term memory neural network. The experimental results showed that the model had a significant advantage in controlling the accumulation of the forecasting error over time and that it was suitable for medium- and long-term clock bias forecasting.…”

Section: Introductionmentioning

confidence: 99%

Improved SSA-Based GRU Neural Network for BDS-3 Satellite Clock Bias Forecasting

Liu,

Kong

et al. 2024

Sensors

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Satellite clock error is a key factor affecting the positioning accuracy of a global navigation satellite system (GNSS). In this paper, we use a gated recurrent unit (GRU) neural network to construct a satellite clock bias forecasting model for the BDS-3 navigation system. In order to further improve the prediction accuracy and stability of the GRU, this paper proposes a satellite clock bias forecasting model, termed ITSSA-GRU, which combines the improved sparrow search algorithm (SSA) and the GRU, avoiding the problems of GRU’s sensitivity to hyperparameters and its tendency to fall into local optimal solutions. The model improves the initialization population phase of the SSA by introducing iterative chaotic mapping and adopts an iterative update strategy based on t-step optimization to enhance the optimization ability of the SSA. Five models, namely, ITSSA-GRU, SSA-GRU, GRU, LSTM, and GM(1,1), are used to forecast the satellite clock bias data in three different types of orbits of the BDS-3 system: MEO, IGSO, and GEO. The experimental results show that, as compared with the other four models, the ITSSA-GRU model has a stronger generalization ability and forecasting effect in the clock bias forecasting of all three types of satellites. Therefore, the ITSSA-GRU model can provide a new means of improving the accuracy of navigation satellite clock bias forecasting to meet the needs of high-precision positioning.

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Clock bias prediction algorithm for navigation satellites based on a supervised learning long short-term memory neural network

Cited by 18 publications

References 12 publications

Long-term autonomous time-keeping of navigation constellations based on sparse sampling LSTM algorithm

Long-term autonomous time-keeping of navigation constellations based on sparse sampling LSTM algorithm

A Systematic Review of Machine Learning Techniques for GNSS Use Cases

Improved SSA-Based GRU Neural Network for BDS-3 Satellite Clock Bias Forecasting

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