Research on External Disturbance Rejection Double Closed-loop Control Method of Wheel-legged Mobile Platform

doi:10.3901/JME.260371

Abstract

Abstract: A double closed-loop control strategy for the wheel-legged mobile platform is proposed to enhance resistance to external disturbances, and it is mainly used to address the difficulty in maintaining platform stability when the body is subjected to strong external perturbations. Firstly, the wheel-end contact force estimator is established by combining the single-leg dynamics model and the recursive least squares method with forgetting factor, dealing with the problem of challenge in obtaining the contact force without ground reaction force sensors. Furthermore, the changes in the additional kinetic energy of the platform's movement in different directions are solved through the motion orbit reference energy method, and based on it, an external disturbance trigger is designed. The linear and angular flexible mass-spring-damping model ideas are used to analyze the mapping relationship between motion parameters such as displacement, velocity, acceleration and equivalent forces and torques in the linear and angular motion of the center of mass of the platform. Considering the influence of the relative position between the wheel end and the center of mass on the virtual force distribution of the legs, the dynamic relationship of the contact force tracking error and the wheel position tracking error is established. Then the double closed-loop control framework of body position closed loop and wheel end force closed loop is built. Finally, simulation and prototype experiment verify the real-time performance and effectiveness of the proposed method.

Key words: wheel-legged mobile platform, external disturbance rejection double closed-loop control, contact force estimation, disturbance detection trigger

CLC Number:

TJ301

XIE Jingshuo, LIU Hui, HAN Lijin, LIU Baoshuai, XIANG Changle, REN Xiaolei. Research on External Disturbance Rejection Double Closed-loop Control Method of Wheel-legged Mobile Platform[J]. Journal of Mechanical Engineering, 2026, 62(7): 196-207.

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http://www.cjmenet.com.cn/EN/Y2026/V62/I7/196

References

[1] LI Xu,ZHOU Haitao,FENG Haibo,et al. Design and experiments of a novel hydraulic wheel-legged robot (WLR)[C]//2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). IEEE,2018:3292-3297.
[2] KLEMM V,MORRA A,SALZMANN C,et al. Ascento:A two-wheeled jumping robot[C]//2019 International Conference on Robotics and Automation (ICRA). IEEE,2019:7515-7521.
[3] KLEMM V,MORRA A,GULICH L,et al. LQR-assisted whole-body control of a wheeled bipedal robot with kinematic loops[J]. IEEE Robotics and Automation Letters,2020,5(2):3745-3752.
[4] 高靖松,金弘哲,朱延河,等. 基于非线性弹簧模型的轮腿自平衡机器人跳跃算法研究[J]. 机械工程学报,2023,59(9):51-62. GAO Jingsong,JIN Hongzhe,ZHU Yanhe,et al. Research on jumping algorithm of wheel-legged self-balancing robot based on nonlinear spring model[J]. Journal of Mechanical Engineering,2023,59(9):51-62.
[5] BJELONIC M,BELLICOSO C,VIRAGH Y,et al. Keep rollin'—whole-body motion control and planning for wheeled quadrupedal robots[J]. IEEE Robotics and Automation Letters,2019,4(2):2116-2123.
[6] 雷涛,徐康,汪首坤,等. 并联六轮腿机器人机身平稳性控制方法研究[J]. 机械工程学报,2021,57(21):34-44. LEI Tao,XU Kang,WANG Shoukun,et al. Research on stability control method of parallel six-wheel-legged robot[J]. Journal of Mechanical Engineering,2021,57(21):34-44.
[7] XU Kang,WANG Shoukun,YUE Binkai,et al. Adaptive impedance control with variable target stiffness for wheel-legged robot on complex unknown terrain[J]. Mechatronics,2020,69:102388.
[8] KHUDHER D,POWELL R. Quadratic programming for inverse kinematics control of a hexapod robot with inequality constraints[C]//2016 International Conference on Robotics:Current Trends and Future Challenges (RCTFC). IEEE,2016:1-5.
[9] MEDEIROS V,JELAVIC E,BJELONIC M,et al. Trajectory optimization for wheeled-legged quadrupedal robots driving in challenging terrain[J]. IEEE Robotics and Automation Letters,2020,5(3):4172-4179.
[10] VIRAGH Y,BJELONIC M,BELLICOSO C,et al. Trajectory optimization for wheeled-legged quadrupedal robots using linearized zmp constraints[J]. IEEE Robotics and Automation Letters,2019,4(2):1633-1640.
[11] NI Liwei,MA Fangwu,GE Linhe,et al. Design and posture control of a wheel-legged robot with actively passively transformable suspension system[J]. Journal of Mechanisms and Robotics,2021,13(1):011014.
[12] 郑怀航,王军政,刘冬琛,等. 融合前馈与姿态预测的并联稳定平台自抗扰控制策略[J]. 机械工程学报,2021,57(9):19-27. ZHENG Huaihang,WANG Junzheng,LIU Dongchen,et al. Active disturbance rejection control strategy of parallel stable platform based on feedforward and attitude prediction[J]. Journal of Mechanical Engineering,2021,57(9):19-27.
[13] RENNER R,BEHNKE S. Instability detection and fall avoidance for a humanoid using attitude sensors and reflexes[C]//2006 IEEE/RSJ International Conference on Intelligent Robots and Systems. IEEE,2006:2967-2973.
[14] ZHOU Siqi,HELWA M,SCHOELLIG A. Design of deep neural networks as add-on blocks for improving impromptu trajectory tracking[C]//2017 IEEE 56th Annual Conference on Decision and Control (CDC). IEEE,2017:5201-5207.
[15] VOLLENWEIDER E,BJELONIC M,KLEMM V,et al. Advanced skills through multiple adversarial motion priors in reinforcement learning[C]//2023 IEEE International Conference on Robotics and Automation (ICRA). IEEE,2023:5120-5126.
[16] 冷晓琨. 双足机器人参数设计及步态控制算法研究[D]. 哈尔滨:哈尔滨工业大学,2020. LENG Xiaokun. Research on parameter design and gait control algorithm of biped robot[D]. Harbin:Harbin Institute of Technology,2020.
[17] 梶田秀司,管贻生. 仿人机器人[M]. 北京:清华大学出版社,2007. SHUJI K,GUAN Yisheng. Humanoid robots[M]. Beijing:Tsinghua University Press,2007.
[18] LI Junheng,NGUYEN Q. Kinodynamics-based pose optimization for humanoid loco-manipulation[J]. arXiv preprint arXiv:2303.04985,2023.