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Study on Deep Space Time Registration Method of Integrated Navigation System Based on Celestial Angle and Velocity Mesurement
- ZHANG Heng1,2, ZHANG Wei1,2, CHEN Xiao1,2
Author information
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1. Shanghai Institute of Satellite Engineering,Shanghai 201109;
2. Shanghai Key Laboratory of Deep Space Technology,Shanghai,201109
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History
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| Received |
Revised |
| 20 Jun 2017 |
21 Jul 2017 |
| Issue Date |
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| 20 May 2022 |
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Combining the celestial angle measurement with the velocity measurement, the deep space integrated navigation system is derived to determine the position and velocity information of deep space probe. The integrated navigation system has the advantages of continuous, autonomous, real-time and high precision measurement. In the multi-sources information fusion process of the integrated navigation system, an unified time standard of multi-sensor data is required. The basic principle of celestial angle and velocity measurement integrated navigation system is clarified. However, there are many factors will cause time asynchrony in the actual system, such as time standard error, sampling period inconsistent, data transmission delay of angle measurement sensors and velocity measurement sensors, which have great influence on the position and the velocity of measurement information. The mechanism of time error in position and velocity estimation of deep space integrated navigation system is analyzed. The time registration method based on interpolation and extrapolation methods is studied, achieving the measurement information synchronization between the angle measurement sensor and the velocity measurement sensor. The simulation results show that the interpolation and extrapolation time registration algorithm can effectively suppress the time error, improve the accuracy of the deep space integrated navigation system.
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References
[1] 张伟, 张恒. 天文导航在航天工程应用中的若干问题及进展[J]. 深空探测学报, 2016,3(3),204-213.
Zhang W,Zhang H.Research on problems of celestial navigation in space engineering[J].Journal of Deep Space Exploration,2016,3(3),204-213.
[2] 陈晓, 尤伟, 黄庆龙. 火星探测巡航段天文自主导航方法研究[J]. 深空探测学报, 2016 ,3(3),214-218.
Chen X,You W,Huang Q L.Research on celestial navigation for Mars missions during the interplanetary cruising[J].Journal of Deep Space Exploration,2016,3(3):214-218.
[3] Lightsey E G, Mogensen A, Burkhart P D, et al. Real-time navigation for Mars missions using the Mars network [J]. Journal of Spacecraft and Rockets, 2008, 45(3):519-533
[4] Harlander J, Reynolds R J, Roesler F L. Spatial heterodyne spectroscopy for the exploration of diffuse interstellar emission lines at far-ultraviolet wavelengths[J]. Astrophysical Journal, 2013, 396(2):730-740
[5] Englert C R,Babcock D D,Harlander J M. Doppler asymmetric spatial heterodyne spectroscopy(DASH):concept and experimental demonstration[J]. Applied Optics,2007,46(29):7297-7307
[6] 房建成,宁晓琳. 深空探测器自主天文导航方法[M]. 西安:西北工业大学出版社,2010.
[7] 张伟,陈晓,尤伟,等. 光谱红移自主导航新方法[J]. 上海航天,2013,30(2):32-33
Zhang W,Chen X,You W,et al.New autonomous navigation method based on redshift[J].Aerospace Shanghai,2013,30(2):32-33
[8] 袁赣南, 袁克非,等. 基于分段重叠的时间配准方法[J]. 敏感器与微系统, 2012, 31(8):48-56.
Yuan G N,Yuan K F,et al.Time registration method based on segmentation overlap[J].Transducer and Microsystem Technologies, 2012, 31(8):48-56.
[9] 敬忠良,肖刚,李振华. 图像融合——理论与应用[M]. 北京:高等教育出版社,2010.
Jing Z L,Xiao G,Li Z H.Image fusion:theory and applications[M].Beijing:Higher Education Press,2010.
[10] Haykin S.Adaptive Filter Theory,Fourth Edition[M].[S. l.]:Pearson Education,2006:366-390.
[11] Yim J R,Crassidis J L,Junkins J L. Autonomous orbit navigation of interplanetary spacecraft[C]//AIAA/AAS Astrodynamics Specialist Conference. Reston,VA:AIAA,2000:53-61.
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