Satellite integrity monitoring for satellite-based augmentation system: an improved covariance-based method-Reference-Cited by-同舟云学术

Satellite integrity monitoring for satellite-based augmentation system: an improved covariance-based method

Published:2022-05-09 Issue:1 Volume:3 Page:
ISSN:2662-1363
Container-title:Satellite Navigation
language:en
Short-container-title:Satell Navig

Author:

Zheng Shuaiyong^ORCID,Gao Mengzhi,Huang Zhigang,Jin Xiaoqin,Li Kun

Abstract

AbstractSatellite integrity monitoring is vital to satellite-based augmentation systems, and can provide the confidence of the differential corrections for each monitored satellite satisfying the stringent safety-of-life requirements. Satellite integrity information includes the user differential range error and the clock-ephemeris covariance which are used to deduce integrity probability. However, the existing direct statistic methods suffer from a low integrity bounding percentage. To address this problem, we develop an improved covariance-based method to determine satellite integrity information and evaluate its performance in the range domain and position domain. Compared with the direct statistic method, the integrity bounding percentage is improved by 24.91% and the availability by 5.63%. Compared with the covariance-based method, the convergence rate for the user differential range error is improved by 8.04%. The proposed method is useful for the satellite integrity monitoring of a satellite-based augmentation system.

Funder

Tianjin University of Technology

Publisher

Springer Science and Business Media LLC

Subject

General Medicine

Link

https://link.springer.com/content/pdf/10.1186/s43020-022-00070-6.pdf

Reference36 articles.

1. Blanch, J., Walter, T., & Enge P. (2012). A clock and ephemeris algorithm for dual-frequency SBAS. In Proceedings of the ION GNSS 2012, Portland, OR (pp. 2513–2519).

2. Blanch, J., Walter, T., Enge, P., Stem, A., & Altshuler, E. (2014). Evaluation of a covariance-based clock and ephemeris error bounding algorithm for SBAS. In Proceedings of the ION GNSS 2014, Florida, USA (pp. 3270–3276).

3. Chen, J., Huang, Z. G., Li, R., & Gao, W. G. (2017a). An efficient algorithm for determining the correspondence between DFREI and s DFRE for a dual-frequency multi-constellation satellite-based augmentation system. In the 10th China Satellite Navigation Conference 2017a, Shanghai, China, (pp. 109–118).

4. Chen, J., Wang, J., & Yuan, H. (2021). Performance analysis of a GNSS multipath detection and mitigation method with two low-cost antennas in RTK positioning. IEEE Sensors Journal, 22(6), 4827–4835.

5. Chen, J. P. (2001). Research of GPS integrity augmentation (pp. 10–110). Information Engineering University.

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