The state-space model identification-based adaptive collaborative multi-satellite simulation system

Yinghong Zhao; Yankai Wang; Chong Zhang

doi:10.1109/WCSE.2013.54

The state-space model identification-based adaptive collaborative multi-satellite simulation system

Yinghong Zhao, Yankai Wang, Chong Zhang

宇航学院

Beijing Institute of Technology

科研成果: 会议稿件 › 论文 › 同行评审

1 引用（Scopus）

摘要

Developing agent-based collaborative multi-satellite formation flying simulation system is of great significance for the study of complex formation change process in the multisatellite formation flying. We first studied the satellite relative kinetic model and consider the effect of J2 perturbation on the model. Then we used the adaptive decoupling generalized minimum variance control method which based on state-space model identification technology to control the model. In order to verify the performance of the control method, we designed a formation flying simulation system. Simulation results showed that the adaptive control method based on state-space model identification could track the desired trajectory in the presence of unknown disturbances and measurement noise when the states are measurable. The simulation system could be used to test the performance of the multi-satellite collaborative control method.

源语言	英语
页	293-297
页数	5
DOI	https://doi.org/10.1109/WCSE.2013.54
出版状态	已出版 - 2013
活动	2013 4th World Congress on Software Engineering, WCSE 2013 - Hong Kong, 中国期限: 3 12月 2013 → 4 12月 2013

会议

会议	2013 4th World Congress on Software Engineering, WCSE 2013
国家/地区	中国
市	Hong Kong
时期	3/12/13 → 4/12/13

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10.1109/WCSE.2013.54

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Zhao, Y., Wang, Y., & Zhang, C. (2013). The state-space model identification-based adaptive collaborative multi-satellite simulation system. 293-297. 论文发表于 2013 4th World Congress on Software Engineering, WCSE 2013, Hong Kong, 中国. https://doi.org/10.1109/WCSE.2013.54

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title = "The state-space model identification-based adaptive collaborative multi-satellite simulation system",

abstract = "Developing agent-based collaborative multi-satellite formation flying simulation system is of great significance for the study of complex formation change process in the multisatellite formation flying. We first studied the satellite relative kinetic model and consider the effect of J2 perturbation on the model. Then we used the adaptive decoupling generalized minimum variance control method which based on state-space model identification technology to control the model. In order to verify the performance of the control method, we designed a formation flying simulation system. Simulation results showed that the adaptive control method based on state-space model identification could track the desired trajectory in the presence of unknown disturbances and measurement noise when the states are measurable. The simulation system could be used to test the performance of the multi-satellite collaborative control method.",

keywords = "Agent-based collaborative multi-satellite simulation system, Formation remain control",

author = "Yinghong Zhao and Yankai Wang and Chong Zhang",

year = "2013",

doi = "10.1109/WCSE.2013.54",

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note = "2013 4th World Congress on Software Engineering, WCSE 2013 ; Conference date: 03-12-2013 Through 04-12-2013",

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AB - Developing agent-based collaborative multi-satellite formation flying simulation system is of great significance for the study of complex formation change process in the multisatellite formation flying. We first studied the satellite relative kinetic model and consider the effect of J2 perturbation on the model. Then we used the adaptive decoupling generalized minimum variance control method which based on state-space model identification technology to control the model. In order to verify the performance of the control method, we designed a formation flying simulation system. Simulation results showed that the adaptive control method based on state-space model identification could track the desired trajectory in the presence of unknown disturbances and measurement noise when the states are measurable. The simulation system could be used to test the performance of the multi-satellite collaborative control method.

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The state-space model identification-based adaptive collaborative multi-satellite simulation system

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