Journal of Systems Engineering and Electronics ›› 2020, Vol. 31 ›› Issue (5): 871-883.doi: 10.23919/JSEE.2020.000067
• Electronics Technology • Previous Articles Next Articles
Xiaoyi XU(
), Chunhui WANG*(), Zhonghe JIN()
Received:2019-11-18
Online:2020-10-30
Published:2020-10-30
Contact:
Chunhui WANG
E-mail:xiaoyixu@zju.edu.cn;hytgwch@zju.edu.cn;jinzh@zju.edu.cn
About author:XU Xiaoyi was born in 1997. She received her B.E. degree from Shanghai University. She is a Ph.D. candidate of the Micro-Satellite Research Center, Zhejiang University. Her research interests include inter-satellite ranging, satellite network, and satellite constellation design. E-mail: Supported by:Xiaoyi XU, Chunhui WANG, Zhonghe JIN. Design, analysis and optimization of random access inter-satellite ranging system[J]. Journal of Systems Engineering and Electronics, 2020, 31(5): 871-883.
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Fig 1
Four-satellite mutual distance measurement method"
Fig 2
Effect of satellite dynamic motion on RAISR"
Fig 3
Algorithm based on polynomial interpolation"
Fig 4
Delay and multiplication method block diagram"
Fig 5
The 2nd-order LPI"
Fig 6
The 3rd-order LPI"
Fig 7
The 4th-order LPI"
Fig 8
The 5th-order LPI"
Fig 9
The 6th-order LPI"
Fig 10
The 7th-order LPI"
Fig 11
The 8th-order LPI"
Fig 12
Test bench"
Fig 13
Connection relationship"
Fig 14
Hardware platform structure functional block diagram"
Fig 15
Workflow of inter-satellite ranging system"
Fig 16
ISD solving method"
Fig 17
ISDA-B and BMIA-B"
Fig 18
ISDB-C and BMIB-C"
Fig 19
ISDC-A and BMIC-A"
Table 1
Ranging error"
| Distance | MSE/m | |
| 0.337 | 56.158 | |
| 0.349 | 63.640 | |
| 0.333 | 114.353 |
Fig 20
ISD solving method using epoch reduction"
Fig 21
Ranging value of SA and SB after epoch reduction"
Table 2
Distance error after epoch reduction"
| Distance | ||||||
| MSE/m | 0.567 | 0.562 | 0.451 | 0.471 | 0.509 | 0.569 |
Fig 22
Ranging results of SA and SB in homologous experiments"
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