Controller design for the sub-axis of large aperture telescope base on fast observation target

Rongqi Ma, Yunxia Xia, Xiang Liu, Liangzhu Yuan, Jiaming Lei, ZhiWeng Wang, Jia-guang Yuan, Tong Zhang, Chunsheng Xiang, Qiang Wang, Chuanxin Luo, Yongmei Huang, Y. Tan, Q. Bao, G. Ren
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Abstract

Compound axis servomechanism (CAS) is the most popular form of structure used in the large aperture telescope (LAT) system in the last few decades. In the control system of the CAS, the sub-axis which is driven by a fast-steering mirror (FSM) plays a decisive role in observation target tracking. In this paper, the kinetic dynamic of fast observation target (FOT) is analyzed by the time-frequency spectrum method. A sub-axis controller base on the FOT’s kinetic dynamic is proposed to improve the tracking performance of the CAS system. Traditional double-loop control is applied in sub-axis control. The inner loop is designed to provide a large bandwidth to cope with the FOT. As for the outer loop, a new control approach that is PIPI double integrations control is introduced to achieve a better tracking performance for the FOT. Additionally, the relationship between time delay and bandwidth of the LAT system is analyzed to demonstrate that the time delay is the main restriction to further improve the bandwidth of a CCD-based sub-axis controller. The theory and the simulation result indicate the proposed approach can improve the tracking performance of the LAT system to a certain extent, but still not sufficient when it comes to the FOT.
基于快速观测目标的大口径望远镜子轴控制器设计
复合轴伺服机构(CAS)是近几十年来在大口径望远镜(LAT)系统中应用最广泛的结构形式。在CAS的控制系统中,由快速转向镜驱动的子轴对观测目标的跟踪起着决定性的作用。本文采用时频谱法对快速观测目标的动力学特性进行了分析。为了提高CAS系统的跟踪性能,提出了一种基于FOT动力学特性的子轴控制器。在分轴控制中采用传统的双环控制。内环的设计是为了提供大带宽来应对FOT。对于外环,引入了PIPI双积分控制的新控制方法,使ft具有更好的跟踪性能。此外,分析了LAT系统的时延与带宽的关系,表明时延是进一步提高基于ccd的子轴控制器带宽的主要制约因素。理论和仿真结果表明,该方法可以在一定程度上提高LAT系统的跟踪性能,但对于FOT来说仍然不够。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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