RESEARCH ON 6-DOF MOTION SYSTEM OF UNMANNED HELICOPTER

被引:0
作者
Zhou, Hongcheng [1 ]
机构
[1] School of Electronic and Information Engineering, Jinling Institute of Technology, Nanjing
来源
Mechatronic Systems and Control | 2024年 / 52卷 / 10期
关键词
attitude control loop; speed control loop; state feedback; Unmanned helicopter;
D O I
10.2316/J.2024.201-0442
中图分类号
学科分类号
摘要
The flight dynamics of unmanned helicopters are the core of their dynamic simulation system. In response to the linearised equation of the unmanned helicopter given, a closed-loop control law for the attitude control loop and speed control loop was designed by introducing state feedback, while satisfying the controllability and observability of the system. The helicopter was transformed from a static unstable object to a stable and controllable object. A 6-DOF motion simulation strategy for the unmanned helicopter circuit and autopilot circuit was proposed, and the unmanned helicopter control system was combined with a 6-DOF motion simulation platform to construct a 6-DOF motion simulation system for unmanned helicopters. Simulation experiments were conducted on typical flight modes of unmanned helicopters, and the simulation results showed that the robustness of the system was greatly improved. © 2024 Acta Press. All rights reserved.
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共 22 条
[1]  
Fang Y., Development prospects for unmanned helicopter systems, Aeronautical Science and Technology, 32, 1, pp. 35-40, (2021)
[2]  
Wan M., Chen M., Yong K., Adaptive tracking control for an unmanned autonomous helicopter using neural network and disturbance observer, Neurocomputing, 468, 2, pp. 296-305, (2022)
[3]  
Hasan A.F.A.J., Humaidi, Mahdi Al-Obaidi A.Sh., Azar A.T., Ibraheem I.K., Al-Dujaili A.Q., Al. Mhdawi A.K., Abdulmajeed F.A., Fractional order extended state observer enhances the performance of controlled tri-copter UAV based on active disturbance rejection control, Mobile robot: Motion control and path planning, pp. 439-487, (2023)
[4]  
Zheng W., Prediction and analysis of robotic arm trajectory based on adaptive control, Mechatronic Systems and Control, 51, 10, pp. 1-9, (2023)
[5]  
Gupta N., Dewan L., Trajectory tracking and balancing control of rotary inverted pendulum system using quasi-sliding mode control, Mechatronic Systems and Control, 50, 1, pp. 1-8, (2022)
[6]  
Ding R., Ding C., Xu Y., Liu W., Yang X., Neural network-based robust integral error sign control for servo motor systems with enhanced disturbance rejection performance, ISA Transactions, 129, pp. 580-591, (2022)
[7]  
Wang B., Cao C., Zhao Q., Yuan X., Zhu Z., Aeroacoustic characteristic analyses of coaxial rotors in hover and forward flight, International Journal of Aeronautical and Space Sciences, 22, 6, pp. 1278-1292, (2021)
[8]  
Seo J., Lee S., Lee J., Choi J., Nonaffine helicopter control design and implementation based on a robust explicit nonlinear model predictive control, IEEE Transactions on Control Systems Technology, 30, 2, pp. 811-818, (2022)
[9]  
Hou J., Chen M., Liu N., Unmanned helicopter control based on radial basis function neural network and extended state observer, Control Theory & Applications, 38, 9, pp. 1361-1371, (2021)
[10]  
Kidambi K.B., Fermuller C., Aloimonos Y., Xu H., Robust nonlinear control based trajectory tracking for quad rotors under uncertainty, IEEE Control Systems Letters, 5, 6, pp. 2042-2047, (2021)
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