Volume 14 Issue 3
May  2021
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WEN Zhong-kai, ZHANG Qing-jun, LI Shuang, LEI Wen-ping, DU Guo-jun. Multi-optical axis parallelism calibration of space photoelectric tracking and aiming system[J]. Chinese Optics, 2021, 14(3): 625-633. doi: 10.37188/CO.2020-0133
Citation: WEN Zhong-kai, ZHANG Qing-jun, LI Shuang, LEI Wen-ping, DU Guo-jun. Multi-optical axis parallelism calibration of space photoelectric tracking and aiming system[J]. Chinese Optics, 2021, 14(3): 625-633. doi: 10.37188/CO.2020-0133

Multi-optical axis parallelism calibration of space photoelectric tracking and aiming system

doi: 10.37188/CO.2020-0133
Funds:  Supported by Science and Technology on space Intelligent Control Laboratory (No. KGJZDSYS-2018-11)
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  • To achieve multi-optical axis calibration of the space photoelectric tracking and aiming system in a vacuum, this paper first designed a set of multi-axis calibration systems according to the accuracy requirements for multi-axis consistency detection of the space photoelectric tracking and aiming system. Then, a detailed error analysis of each subsystem of the multi-axis calibration system was conducted, and the methods to restrain the influence of error in the key subsystem were given. After that, the technical tests of the space photoelectric tracking and aiming system of the Communications Technology Experiment Satellite 3 were implemented in laboratory and vacuum environments, and the error sources and test accuracy of the multi-axis calibration system in the two test environments were analyzed and the test results were given. Finally, the accuracy of the multi-axis calibration system was verified. The final results show that the calibration accuracy of the multi-axis calibration system in this paper is 0.998" in the laboratory test environment, and the calibration error of the parallelism of transmitter and receiver is 1.165"; the calibration accuracy is 1.219" in the vacuum test environment, and the calibration error of parallelism of transmitter and receiver is 1.359". These results fully meet the 1.5" multi-optical axis detection accuracy requirements of the space photoelectric tracking system, and provide support for research in related engineering applications.

     

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