Distributed Localization of Non-Cooperative Targets in Non-Coplanar Rendezvous Processes

被引：0

作者：

Zhen, Zihan ^{[1
]}

Yu, Feng ^{[1
]}

机构：

[1] Nanjing Univ Aeronaut & Astronaut, Coll Astronaut, Nanjing 211106, Peoples R China

来源：

AEROSPACE | 2024年 / 11卷 / 12期

关键词：

non-cooperative target; line of sight; NSGA-III; NONDOMINATED SORTING APPROACH; ANGLES-ONLY NAVIGATION; ALGORITHM; OBSERVABILITY;

D O I：

10.3390/aerospace11121039

中图分类号：

V [航空、航天];

学科分类号：

08 ; 0825 ;

摘要：

Precise positioning of non-cooperative targets is important for maintaining spacecraft operational environments in orbit. In order to address the challenges of non-cooperative target localization during non-coplanar rendezvous, this study develops a distributed cooperative localization scheme. First, a three-line-of-sight positioning method for long-range targets in non-coplanar orbits is proposed. Second, a distributed extended Kalman filter based on a consensus algorithm is designed, which reduces observation dimensions and increases system robustness. Subsequently, the rendezvous configuration optimization problem for long-range non-coplanar targets is transformed into a numerical optimization problem. Finally, an improved NSGA-III algorithm is proposed by introducing normal distribution crossover (NDX) and a cosine-like mutation distribution index to optimize the rendezvous configuration. A simulation shows that the methods proposed are effective, and the improved NSGA-III is superior to traditional algorithms in terms of search range and convergence speed. After configuration optimization, the performance of the system has been greatly improved, with better positioning accuracy and stronger robustness.

引用

页数：17

共 26 条

[1]

Gao X.-H., Liang B., Pan L., Du X.-D., Distributed relative navigation of GEO non-cooperative target based on multiple line-of-sight measurements, Yuhang Xuebao/J. Astronaut, 36, pp. 292-299, (2015)

[2]

Woffinden D., Geller D., Optimal orbital rendezvous maneuvering for angles-only navigation, J. Guid. Control Dyn, 32, pp. 1382-1387, (2009)

[3]

Li J.R., Li H.Y., Tang G.J., Luo Y., Research on the strategy of angles-only relative navigation for autonomous rendezvous, Sci. China Tech. Sci, 54, pp. 1865-1872, (2011)

[4]

Geller D., Klein I., Angles-only navigation state observability during orbital proximity opera- tions, J. Guid. Control Dyn, 37, pp. 1976-1983, (2014)

[5]

Gong B., Li W., Li S., Ma W., Zheng L., Angles-only relative navigation algorithm for close-in proximity of space non-cooperative target, J. Chin. Inert. Technol, 2, pp. 217-231, (2018)

[6]

Sullivan J., Koenig A., D'Amico S., Improved maneuver-free approach to angles-only navigation for space rendezvous, Proceedings of the 26th AAS/AIAA Space Flight Mechanics Meeting

[7]

Du R., Liao W., Zhang X., Non-linear Dynamics Method to Angles-Only Navigation for Non-cooperative Rendezvous of Spacecraft, Trans. Nanjing Univ. Aeronaut. Astronaut, 39, pp. 400-414, (2022)

[8]

Gaias G., D'Amico S., Ardaens J., Angles-only navigation to a noncooperative satellite using relative orbital elements, J. Guid. Control Dyn, 37, pp. 439-451, (2014)

[9]

Newman B., Lovell A., Pratt E., Duncan E., Hybrid linear-nonlinear initial determination with single iteration refinement for relative motion, Proceedings of the 25th AAS/AIAA Space Flight Mechanics Meeting

[10]

Chen T., Xu S.J., Approach guidance with double-line-of-sight measuring navigation constraint for autonomous rendezvous, J. Guid. Control Dyn, 34, pp. 678-687, (2011)

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