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Research on High-Stability Composite Control Methods for Telescope Pointing Systems under Multiple Disturbances.

Authors :
Zhang, Rui
Zhao, Kai
Fang, Sijun
Fan, Wentong
Hai, Hongwen
Luo, Jian
Li, Bohong
Sun, Qicheng
Song, Jie
Yan, Yong
Source :
Sensors (14248220); May2024, Vol. 24 Issue 9, p2907, 20p
Publication Year :
2024

Abstract

During the operation of space gravitational wave detectors, the constellation configuration formed by three satellites gradually deviates from the ideal 60° angle due to the periodic variations in orbits. To ensure the stability of inter-satellite laser links, active compensation of the breathing angle variation within the constellation plane is achieved by rotating the optical subassembly through the telescope pointing mechanism. This paper proposes a high-performance robust composite control method designed to enhance the robust stability, disturbance rejection, and tracking performance of the telescope pointing system. Specifically, based on the dynamic model of the telescope pointing mechanism and the disturbance noise model, an H<subscript>∞</subscript> controller has been designed to ensure system stability and disturbance rejection capabilities. Meanwhile, employing the method of an H<subscript>∞</subscript> norm optimized disturbance observer (HODOB) enhances the nonlinear friction rejection ability of the telescope pointing system. The simulation results indicate that, compared to the traditional disturbance observer (DOB) design, utilizing the HODOB method can enhance the tracking accuracy and pointing stability of the telescope pointing system by an order of magnitude. Furthermore, the proposed composite control method improves the overall system performance, ensuring that the stability of the telescope pointing system meets the 10 nrad/Hz<superscript>1/2</superscript> @0.1 mHz~1 Hz requirement specified for the TianQin mission. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
14248220
Volume :
24
Issue :
9
Database :
Complementary Index
Journal :
Sensors (14248220)
Publication Type :
Academic Journal
Accession number :
177183754
Full Text :
https://doi.org/10.3390/s24092907