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Satellite-Ground Link Planning Method for LEO Satellite Navigation Augmentation Network in the Case of Multiple Ground Stations Read chapter Read first chapter

2022 | OriginalPaper | Chapter

Applications and Prospects for Autonomous Navigation Technology in a Satellite Navigation System

Authors : Wei Zhou, Hongliang Cai, Haihong Wang, Qiuli Chen, Xia Lin, Jinglei Guo, Xiaojiie Li, Chengpan Tang, Ruiqiang Shao, Junyang Pan, Weisong Jia, Ziqiang Li

Published in: China Satellite Navigation Conference (CSNC 2022) Proceedings

Publisher: Springer Nature Singapore

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Abstract

Autonomous constellation navigation is an important means for improving the continuous delivery of services by satellite navigation systems when experiencing conditions such as major disasters and failure of ground operation control facilities. It is also a useful supplement to the normal operation and control mode, which can reduce dependence on the ground facilities while lowering operating costs. This article introduces a method for evaluating experiments on the autonomous constellation navigation of satellite navigation systems. These experiments were based on 12 days of BDS-3 satellite observation data. The evaluation results show that for the 12 days of autonomous constellation navigation, the user range error of the satellite orbit was 2.5 m, the accuracy of clock error was 3 ns, and the timekeeping accuracy was approximately 1373 ns. The pseudorange observation data of 7 domestic stations and 10 global stations of the International GNSS Monitoring and Assessment System (iGMAS) was used to evaluate the positioning accuracy. The results show a single-frequency horizontal positioning accuracy of 7.4 m, an altitude positioning accuracy of 9.6 m, a dual-frequency horizontal positioning accuracy of 7.1 m, and an elevation positioning accuracy of 8.9 m. Based on the results of the experiment, this paper analyses the time-space reference drift problem that affects the accuracy of autonomous navigation space signals and proposes an optimized solution.

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Metadata
Title
Applications and Prospects for Autonomous Navigation Technology in a Satellite Navigation System
Authors
Wei Zhou
Hongliang Cai
Haihong Wang
Qiuli Chen
Xia Lin
Jinglei Guo
Xiaojiie Li
Chengpan Tang
Ruiqiang Shao
Junyang Pan
Weisong Jia
Ziqiang Li
Copyright Year
2022
Publisher
Springer Nature Singapore
Book
China Satellite Navigation Conference (CSNC 2022) Proceedings

Print ISBN: 978-981-19-2579-5

Electronic ISBN: 978-981-19-2580-1

Copyright Year: 2022

DOI
https://doi.org/10.1007/978-981-19-2580-1_28