Initial Assessment of the LEO Based Navigation Signal Augmentation System from Luojia-1A Satellite

Wang, Lei; Chen, Ruizhi; Li, Deren; Guo, Zhang; Shen, Xin; Yu, Baoguo; Wu, Cailun; Xie, Shengli; Zhang, Peng; Li, Ming

doi:10.3390/s18113919

Cited by 64 publications

(43 citation statements)

References 37 publications

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“…Signal augmentation technologies refer to the technology of signal extension which provides a signal source that is capable of transmitting ranging signals to expand and extend GNSS. Through signal augmentation technologies, users can obtain accurate and reliable locations in scenarios where GNSS cannot be used or does not work well (Ma 2018;Reid et al 2016;Wang et al 2018a). To overcome the vulnerability of the GNSS system from the perspective of availability, reliability, and anti-interference, some researchers both in China and abroad have proposed that LEO satellites broadcast a ranging signal to augment the performance of the satellite navigation system that is composed of Medium Earth Orbit (MEO) and High Earth Orbit (HEO) satellites.…”

Section: Technologies Of Leo Satellite Segment Preliminary Informationmentioning

confidence: 99%

“…There are many advantages of using LEO satellites for satellite navigation signal augmentation in addition to the increase in visibility and the improvement to accuracy (Wang et al 2018b), including the following: (1) Leo satellites move fast which helps to speed up the convergence of the accuracy positioning filter. Results show that the convergence time of precise point positioning is shortened from 30 to 1-2 min when using LEO; (2) As LEO satellites are at low altitude, the signal-in-space is stronger than that of the MEO or HEO satellites.…”

Section: Technologies Of Leo Satellite Segment Preliminary Informationmentioning

confidence: 99%

“…The Luojia-1A satellite has the main function of providing precise measurements of orbit and timing, storing GNSS onboard observations and downloading to the ground, and LEO augmentation experiments. The Luojia-1A satellite was used to carry out experiments investigating the navigation signal augmentation based on the LEO satellite platform in China for the first time (Wang et al 2018a).…”

Section: Research Progressmentioning

confidence: 99%

“…9. Users can simultaneously receive a dual frequency signal from BDS, GPS, and Luojia-1A in order to achieve the hybrid satellite constellation positioning of the HEO, MEO, and LEO satellites, improving the performance in navigation and positioning (Wang et al 2018b). As the frequency of the augmentation signal from Luojia-1A is different from that of the existing GNSS signal, a modified receiver with specific receiving antenna is installed onto the equipment of a user to collect the signals from both GNSS and Luojia-1A.…”

Section: Research Progressmentioning

confidence: 99%

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Advances in BeiDou Navigation Satellite System (BDS) and satellite navigation augmentation technologies

Zheng

Wang

et al. 2020

Satell Navig

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Several noteworthy breakthroughs have been made with the BeiDou Navigation Satellite System (BDS) and other global navigation satellite systems as well as the associated augmentation systems, such as the commissioning of the BDS-3 preliminary system and the successful launch of the first BDS-3 GEO satellite which carries the satellitebased augmentation payload. Presently, BDS can provide basic services globally, and its augmentation system is also being tested. This paper gives an overview of BDS and satellite navigation augmentation technologies. This overview is divided into four parts, which include the system segment technologies, satellite segment technologies, propagation segment technologies, and user segment technologies. In each part, these technologies are described from the perspectives of preliminary information, research progress, and summary. Moreover, the significance and progress of the BeiDou Satellite-based Augmentation System (BDSBAS), low earth orbit augmentation, and the national BeiDou ground-based augmentation system are presented, along with the airborne-based augmentation system. Furthermore, the conclusions and discussions covering popular topics for research, frontiers in research and development, achievements, and suggestions are listed for future research.

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Section: Technologies Of Leo Satellite Segment Preliminary Informationmentioning

confidence: 99%

Section: Technologies Of Leo Satellite Segment Preliminary Informationmentioning

confidence: 99%

Section: Research Progressmentioning

confidence: 99%

Section: Research Progressmentioning

confidence: 99%

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Advances in BeiDou Navigation Satellite System (BDS) and satellite navigation augmentation technologies

Zheng

Wang

et al. 2020

Satell Navig

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“…The real-time POD capacity will improve the LEO satellites' performance, such as cutting the radio occultation data processing latency [10,11], reducing the dependency of the ground control point for the remote sensing satellite imagery data processing, and supporting the LEO navigation augmentation applications [12][13][14]. The Luojia-1A satellite has demonstrated the potential benefit of navigation signal augmentation from the LEO satellite [15,16].Supporting the real-time PPP by the predicted clocks attracts much attention in the GNSS communities. The international GNSS service (IGS) released its clock prediction product (known as the ultra-rapid products) to support the RTPPP applications.…”

mentioning

confidence: 99%

A Practical Adaptive Clock Offset Prediction Model for the Beidou-2 System

Wang

et al. 2019

Remote Sensing

Self Cite

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The predicted navigation satellite clock offsets are crucial to support real-time global navigation satellite system (GNSS) precise positioning applications, especially for those applications difficult to access the real-time data stream, such as the low earth orbit (LEO) autonomous precise orbit determination. Currently, the clock prediction for the Chinese BeiDou system is still challenging to meet the precise positioning requirement. The onboard clocks of BeiDou satellites are provided by different manufacturers, and the clocks’ switch events are more frequent. Considering the satellite-specified and temporal variation of the BeiDou clocks characteristics, we intend to use an adaptive model for BeiDou clock prediction. During clock prediction, we identify different models for BeiDou clocks’ characteristics, and then address the optimal model with a cross-validation procedure. The model achieving the minimum variance in the cross-validation procedure is used for the final clock prediction. We compared the prediction results of our method with two well-recognized BeiDou ultra-rapid clock products, named GBU-P and ISU-P, respectively. The comparison results indicate that the adaptive model achieves about 1-ns precision for 3-h prediction, which corresponds to 47.3% and 32.1% precision improvement compared to the GBU-P and ISU-P products, respectively. The efficiency of the predicted clocks is further validated with the precise point positioning (PPP) data processing. The results indicate that the static PPP solution precision is improved by 21.6%–30.0% compared to the current predicted clock product. The precision improvement in kinematic PPP is even more significant, which reaches 46.7%–53.9% with respect to these GBU-P and ISU-P products. Therefore, the proposed adaptive model is a practical and an efficient way to improve the BeiDou clock prediction.

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