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Differential Timing Method Based on Modified Traceability Model

Published online by Cambridge University Press:  22 June 2020

Ying Liu
Affiliation:
(State Key Laboratory of Advanced Optical Communication Systems and Networks, Department of Electronic Engineering, Shanghai Jiao Tong University, Shanghai, China) (Beijing Institute of Tracking and Telecommunication Technology, Beijing, China)
Wenhai Jiao
Affiliation:
(State Key Laboratory of Advanced Optical Communication Systems and Networks, Department of Electronic Engineering, Shanghai Jiao Tong University, Shanghai, China)
Longxia Xu*
Affiliation:
(National Time Service Center, Chinese Academy of Sciences, Xi'an, China) (Key Laboratory of Precision Navigation Positioning and Timing, Chinese Academy of Sciences, Xi'an, China)
Xiaohui Li
Affiliation:
(National Time Service Center, Chinese Academy of Sciences, Xi'an, China) (Key Laboratory of Precision Navigation Positioning and Timing, Chinese Academy of Sciences, Xi'an, China)
*

Abstract

The common view time transfer and two-way time and frequency transfer methods are currently the main means for achieving time synchronisation at nanosecond level. However, these methods have some limitations in real time and cost, which limit their wide applications in many fields, such as time synchronisation among base stations of the upcoming 5G network. In order to meet the requirements of nanosecond time synchronisation, a low-cost differential timing method is proposed in this paper by changing the manner of generation of traceability model parameters in GNSS navigation messages. The time deviation between GNSS system time and the timing laboratory that maintains Coordinated Universal Time (UTC) kept by timing laboratory named k (UTC(k)) is monitored by receiving the GNSS signal in space with monitoring receivers. The new traceability model parameters are generated with the monitored time deviations and then broadcast to users through the GNSS navigation message. The precision of the one-way timing method can be improved from tens of nanoseconds to the order of several nanoseconds with the proposed method. In addition, there are obvious advantages to carry out this method on the geostationary satellites in the BeiDou navigation satellite (BDS) constellation. The proposed method is verified on an experimental platform based on the UTC(NTSC) time frequency signal and the geostationary satellites in the BDS-3 constellation.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2020

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References

REFERENCES

BDS-OS-PS-2.0,2018-12 (2018). BeiDou Navigation Satellite System Open Service Performance Standard (Version 2.0). China Satellite Navigation Office, December 2018.Google Scholar
BeiDou Navigation Satellite System. (2019). Signal in Space Interface Control Document. Open Service Signal B1I (Version 3.0). China Satellite Navigation Office, February 2019.Google Scholar
De Bakker, P. F., Tiberius, C. C. J. M., van der Marel, H., et al. (2012). Short and zero baseline analysis of GPS L1 C/A, L5Q, GIOVE E1B, and E5aQ signals. GPS Solutions, 16(1), 5364.CrossRefGoogle Scholar
Dong, S. and Wu, H. (2012). Study on GNSS Time Reference System and its Traceability. Applied Mechanics and Materials, 2012, 263–266:2031–2034.Google Scholar
European GNSS (Galileo). (2010). Open Service Signal in Space Interface Control Document, OD SIS ICD, Issue 1, February 2010.Google Scholar
Feng, W., Chen, X., Wu, X., et al. (2011). An influence of space's latitude on differential ionospheric grid performance. Journal of Geodesy and Geodynamics, 31(4), 135138.Google Scholar
Ge, Y., Xue, L. and Li, J. (2018). Study on the concept of time war in the US Air Force. Aero Dynamic Missile Journal, 1(5), 1114.Google Scholar
Ge, Y., Xue, L. and Li, J. (2019). Analysis of the development trends of US Army PNT capability. Navigation Positioning & Timing, 6(2), 1218.Google Scholar
Huang, C., Yang, X. and Cheng, X. (2019). A measurement method of ground station equipment time delay for transfer ranging system. Navigation Positioning &Timing, 6(1), 8186.Google Scholar
Levine, J. (2008). A review of time and frequency transfer methods. Metrologia, 45(6), 162174.10.1088/0026-1394/45/6/S22CrossRefGoogle Scholar
Lewandowski, W. and Arias, E. F. (2011). GNSS times and UTC. Metrologia, 48, S219S224.CrossRefGoogle Scholar
Meng, L., Liu, Y., Wang, W., et al. (2018). Gross error of detection algorithm in time traceability data via optical fiber time transfer technique. Chinese Journal of Scientific Instrument, 39(9), 114120.Google Scholar
Nicolini, L. and Caporali, A. (2018). Investigation on reference frames and time systems in multi-GNSS. Remote Sensing, 10(2), 8085.CrossRefGoogle Scholar
Romisch, S., Zhang, V., Parker, T. E., et al. (2012). Enabling Accurate Differential Calibration of Modern GPS Receivers. Proceedings of Annual Precise Time & Time Interval Systems & Applications Meeting 26–29 November 2012. Reston, Virginia, USA, pp. 203210.Google Scholar
Schempp, T., Burke, J., and Rubin, A. WAAS Benefits of GEO Ranging. Proceedings of ION GNSS 2008. Savannah [s. n.], 2008: 19031910.Google Scholar
Sha, H., Zhan, J. W., Wang, J. H., et al. (2013). Comparison and Research on the Timing Method of BeiDou Navigation Satellite System. The 4th China Satellite Navigation Academic Annual Conference, May 15–17, 2013, Wuhan, China.Google Scholar
Wang, T. (2014). Study on the Timing Performance Evaluation of BeiDou Navigation Satellite System. Xi'an, China: Chang'an Univeristy.Google Scholar
Xiao, L., Sun, F., Li, Y., et al. (2016). The navigation performance analysis of IGSO/GEO satellite for BeiDou. GNSS World of China, 41(3), 1620.Google Scholar
Young, L., Munson, T., Meehan, T., et al. (2009). GNSS Receiver Calibration (Invited), AGU Fall Meeting. AGU Fall Meeting Abstracts.Google Scholar
Zhang, H., Yang, H., Shao, W. and Yao, J. (2019). Application of BeiDou RNSS timing technology in smart grid lightning locating system. Telecommunications Science, 35(2), 134141.Google Scholar
Zhu, F. (2015). The Time Parameter of Satellite Navigation and its Test Method. Xi'an: Chinese Academy of Sciences (National Time Service Center).Google Scholar