Research on nonlinear control methods for on-orbit servicing with visual positioning system

2011 IEEE International Conference on Computational Intelligence for Measurement Systems and Applications (CIMSA) Proceedings Pub Date : 2011-10-27 DOI:10.1109/CIMSA.2011.6059923

Weiwei Yang, Yong Zhao, Yiyong Huang, Xiaoqian Chen, Zhenguo Wang

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Abstract

A new laboratory test bed of on-orbit servicing system is introduced that enables simulation of the autonomous approach and docking of a chaser spacecraft to a target spacecraft with similar mass. The test bed system consists of a chaser and a target spacecraft simulator floating via air pads on a marble platform. Relative navigation of the chaser spacecraft is obtained by the united measurements with a single-camera visual sensor and IMU, through Kalman filters. Six cold-gas on-off thrusters and a flywheel are used for the translation and rotation of the chaser simulator. Considering the uncertainties in model, two nonlinear control algorithms, sliding mode control and PID control based on Back-Propagation Neural Network are adopted. Numerical simulations and ground experimental results are presented with comparison for an autonomous proximity maneuver and docking of the chaser simulator to the nonfloating target, which valid the efficiency of the sliding mode control and the test bed capabilities.

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基于视觉定位的在轨服务非线性控制方法研究

介绍了一种新型在轨服务系统实验室试验台，实现了追星航天器与质量相近的目标航天器的自主进近与对接仿真。测试平台系统由一个追逐器和一个目标航天器模拟器组成，通过一个大理石平台上的空气垫漂浮。通过卡尔曼滤波，利用单相机视觉传感器和IMU进行联合测量，获得了跟踪飞行器的相对导航。六个冷气开关推进器和一个飞轮用于追逐模拟器的平移和旋转。考虑到模型的不确定性，采用了滑模控制和基于反向传播神经网络的PID控制两种非线性控制算法。仿真结果与地面实验结果进行了比较，验证了滑模控制的有效性和试验台的性能。

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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来源期刊

2011 IEEE International Conference on Computational Intelligence for Measurement Systems and Applications (CIMSA) Proceedings

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