RBF Neural Network Compensation Sliding Mode Control Strategy for Flexible Space Manipulators

被引：0

作者：

Li, Xiao-Peng ^{[1
]}

Fu, Jia-Xing ^{[1
]}

Liu, Hai-Long ^{[1
]}

Yin, Meng ^{[2
]}

机构：

[1] School of Mechanical Engineering & Automation, Northeastern University, Shenyang

[2] Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen

来源：

Dongbei Daxue Xuebao/Journal of Northeastern University | 2024年 / 45卷 / 09期

关键词：

dynamic modeling; flexible space manipulator; neural network compensation; sliding mode control;

D O I：

10.12068/j.issn.1005-3026.2024.09.006

中图分类号：

学科分类号：

摘要：

Flexible structures cause the dynamic parameters of flexible space manipulators to change with time，which reduces the accuracy of tracking control. The lighter mass and the larger ratio of length to radius may result in the vibration of flexible space manipulators during their movement. To solve the above problems，a dynamic model of a flexible space manipulator considering two‑dimensional deformation and disturbance torque is established，and a simplified non‑linear dynamic formula is derived. On this basis，a control law is designed to identify and compensate for the time‑varying term and disturbance torque in the flexible space manipulator using the radial basis function （RBF） neural network. Then，using the hyperbolic tangent function as the approximation rate，a sliding mode control strategy is proposed. Finally，through simulation and ground physical prototype experiment，it can be concluded that in the design of control laws for flexible space manipulators， the control strategy with neural network compensation effectively reduces the impact of disturbance torque on the flexible space manipulator. By using the tanh function instead of the sgn function，the fluctuation of input torque can be reduced，and the effectiveness of the RBF neural network compensation sliding mode control strategy is verified. © 2024 Northeast University. All rights reserved.

引用

页码：1258 / 1267

页数：9

共 23 条

[11] Wang Hong, Zheng Tian-qi, RBF network adaptive control based on SMC compensation for six‑axis manipulator［J］, Journal of Northeastern University（Natural Science）, 38, 11, pp. 1601-1606, (2017)
[12] Chen Zeng, Hai Ai, Li Chen, Operation force/ pose impedance control of space manipulator in orbit［J］, Chinese Journal of Mechanical Engineering, 58, 3, pp. 84-94, (2022)
[13] Wu Hao, Et al., Adaptive sliding mode control for flexible joint space mechanical arms［J］, Journal of Astronautics, 40, 6, pp. 703-710, (2019)
[14] Yin X M, ，Wang B，Liu L，et al.Disturbance observer‑based gain adaptation high‑order sliding mode control of hypersonic vehicles［J］, Aerospace Science and Technology, 89, pp. 19-30, (2019)
[15] Yao Q J., Adaptive trajectory tracking control of a free‑flying space manipulator with guaranteed prescribed performance and actuator saturation［J］, Acta Astronautica, 185, pp. 283-298, (2021)
[16] Zhang Jian-yu, Gao Tian-yu, Et al., Continuous non‑singular terminal sliding mode control of space manipulator based on adaptive time delay estimation［J］, Journal of Mechanical Engineering, 57, 11, pp. 177-183, (2021)
[17] Wu S X，, Chen L，, Zhang D X，, Et al., Disturbance observer‑based fixed time sliding mode control for spacecraft proximity operations with coupled dynamics［J］, Advances in Space Research, 66, 9, pp. 2179-2193, (2020)
[18] Jia S Y, Shan J J., Finite‑time trajectory tracking control of space manipulator under actuator saturation ［J］, IEEE Transactions on Industrial Electronics, 67, 3, pp. 2086-2096, (2020)
[19] Johanastrom K，, de Canudas W C., Revisiting the LuGre friction model［J］, IEEE Control Systems Magazine, 28, 6, pp. 101-114, (2008)
[20] Shang D Y，, Li X P，, Yin M，, Et al., Tracking control strategy for space flexible manipulator considering nonlinear friction torque based on adaptive fuzzy compensation sliding mode controller［J］, Advances in Space Research, 71, 9, pp. 3661-3680, (2023)

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