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Bruno Belzile, D. St-Onge (2022)
ARIES: Cylindrical Pendulum Actuated Explorer SphereIEEE/ASME Transactions on Mechatronics, 27
Chunyan Zhang, Xinxing Jiang, Xiangyu Liu, Dan Zhang (2021)
Single-Loop Full R Joints of Multi-Mode Omnidirectional Ground Mobile RobotTehnicki vjesnik - Technical Gazette
Mien Van, S. Ge (2020)
Adaptive Fuzzy Integral Sliding-Mode Control for Robust Fault-Tolerant Control of Robot Manipulators With Disturbance ObserverIEEE Transactions on Fuzzy Systems, 29
B. DeJong, Ernur Karadoğan, K. Yelamarthi, James Hasbany (2017)
Design and Analysis of a Four-Pendulum Omnidirectional Spherical RobotJournal of Intelligent & Robotic Systems, 86
Saleh Mobayen, S. Mostafavi, A. Fekih (2020)
Non-Singular Fast Terminal Sliding Mode Control With Disturbance Observer for Underactuated Robotic ManipulatorsIEEE Access, 8
Wen‐Hua Chen, D. Ballance, P. Gawthrop, J. O'Reilly (2000)
A nonlinear disturbance observer for robotic manipulatorsIEEE Trans. Ind. Electron., 47
Jian Huang, Mengshi Zhang, Songhyok Ri, C. Xiong, Zhijun Li, Yu Kang (2020)
High-Order Disturbance-Observer-Based Sliding Mode Control for Mobile Wheeled Inverted Pendulum SystemsIEEE Transactions on Industrial Electronics, 67
R. Fareh, S. Khadraoui, Mohmoud Abdallah, Mohammed Baziyad, M. Bettayeb (2021)
Active disturbance rejection control for robotic systems: A reviewMechatronics
Jinglai Shen, A. Sanyal, N. Chaturvedi, D. Bernstein, H. Mcclamroch (2004)
Dynamics and control of a 3D pendulum2004 43rd IEEE Conference on Decision and Control (CDC) (IEEE Cat. No.04CH37601), 1
A. Kilin, E. Pivovarova (2020)
Stability and Stabilization of Steady Rotations of a Spherical Robot on a Vibrating BaseRegular and Chaotic Dynamics, 25
Minggang Li, Hanxu Sun, Long Ma, Panpan Gao, Dongshui Huo, Zhantong Wang, Ping Sun (2023)
Special spherical mobile robot for planetary surface exploration: A reviewInternational Journal of Advanced Robotic Systems, 20
Meng Li, He Chen, Ran Zhang (2022)
An Input Dead Zones Considered Adaptive Fuzzy Control Approach for Double Pendulum Cranes With Variable Rope LengthsIEEE/ASME Transactions on Mechatronics, 27
R. Chase, A. Pandya (2012)
A Review of Active Mechanical Driving Principles of Spherical RobotsRobotics, 1
Xin Hu, Xinjiang Wei, Huifeng Zhang, W. Xie, Qiang Zhang (2020)
Composite anti-disturbance dynamic positioning of vessels with modelling uncertainties and disturbancesApplied Ocean Research
Umut Mayetin, S. Kucuk (2021)
A low cost 3-DOF force sensing unit design for wrist rehabilitation robotsMechatronics, 78
Yihui Gong, Lin Li, Shengbo Qi, Changbin Wang, Dalei Song (2021)
Enhanced disturbance observer-based robust yaw servo control for ROVs with multi-vector propulsionInd. Robot, 48
Metin Toz, S. Kucuk (2015)
Parallel manipulator software tool for design, analysis, and simulation of 195 GSP mechanismsComputer Applications in Engineering Education, 23
Animesh Singhal, Sahil Modi, Abhishek Gupta, L. Vachhani, Omkar Ghag (2023)
Pendulum Actuated Spherical Robot: Dynamic Modeling & Analysis for Wobble & PrecessionArXiv, abs/2301.05859
Germán Hernández, Juan Díaz-Téllez, J. Estevez-Carreon, R. García-Ramirez (2023)
ADRC Attitude Controller Based on ROS for a Two-Wheeled Self-Balancing Mobile RobotIEEE Access, 11
Futao Wang, C. Li, S. Niu, Pengfei Wang, Huaisong Wu, Bingyang Li (2022)
Design and Analysis of a Spherical Robot with Rolling and Jumping Modes for Deep Space ExplorationMachines
Zhiqiang Su, Mengqian Zhou, Fang-fang Han, Yi-wu Zhu, Dalei Song, Tingting Guo (2018)
Attitude control of underwater glider combined reinforcement learning with active disturbance rejection controlJournal of Marine Science and Technology
Yanzhang Yao, W. Wang, Yue Qiao, Zhihang He, Fusheng Liu, Xuelong Li, Xinxin Liu, D. Zou, Tong Zhang (2021)
A novel series-parallel hybrid robot for climbing transmission towerInd. Robot, 48
Marek Bujňák, R. Pirník, K. Rástočný, A. Janota, Dušan Nemec, Pavol Kuchár, T. Tichý, Zbigniew Lukasik (2022)
Spherical Robots for Special Purposes: A Review on Current PossibilitiesSensors (Basel, Switzerland), 22
K. Yoshida, I. Kawanishi, H. Kawabe (1997)
Stabilizing control for a single pendulum by moving the center of gravity: theory and experimentProceedings of the 1997 American Control Conference (Cat. No.97CH36041), 5
Carina Veil, Daniel Müller, O. Sawodny (2021)
Nonlinear disturbance observers for robotic continuum manipulatorsMechatronics
Saeed Moazami, H. Zargarzadeh, S. Palanki (2019)
Kinematics of Spherical Robots Rolling Over 3D TerrainsArXiv, abs/1906.05228
Mete Aydemir, K. Arıkan (2020)
Evaluation of the Disturbance Rejection Performance of an Aerial ManipulatorJournal of Intelligent & Robotic Systems, 97
A. Kilin, E. Pivovarova (2022)
Motion Control of the Spherical Robot Rolling on a Vibrating PlaneApplied Mathematical Modelling
Gang Li, Jinpeng Yu, Xinkai Chen (2021)
Adaptive Fuzzy Neural Network Command Filtered Impedance Control of Constrained Robotic Manipulators With Disturbance ObserverIEEE Transactions on Neural Networks and Learning Systems, 34
B. Brahmi, Mark Driscoll, Ibrahim Bojairami, M. Saad, A. Brahmi (2020)
Novel adaptive impedance control for exoskeleton robot for rehabilitation using a nonlinear time-delay disturbance observer.ISA transactions
Peng Yang, Xiao Ma, Jie Wang, Gaowei Zhang, Yan Zhang, Lingling Chen (2019)
Disturbance Observer-Based Terminal Sliding Mode Control of a 5-DOF Upper-Limb Exoskeleton RobotIEEE Access, 7
Yixu Wang, Xiaoqing Guan, Tao Hu, Ziang Zhang, You Wang, Zhan Wang, Yifan Liu, Guang Li (2021)
Fuzzy PID Controller Based on Yaw Angle Prediction of a Spherical Robot*2021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)
B. Zhao, Mantian Li, Haitao Yu, Haiyan Hu, Lining Sun (2010)
Dynamics and motion control of a two pendulums driven spherical robot2010 IEEE/RSJ International Conference on Intelligent Robots and Systems
Umut Mayetin, S. Kucuk (2022)
Design and Experimental Evaluation of a Low Cost, Portable, 3-DOF Wrist Rehabilitation Robot with High Physical Human–Robot InteractionJournal of Intelligent & Robotic Systems, 106
E. Sariyildiz, R. Oboe, K. Ohnishi (2019)
Disturbance Observer-Based Robust Control and Its Applications: 35th Anniversary OverviewIEEE Transactions on Industrial Electronics, 67
S. Kucuk (2018)
Dexterous Workspace Optimization for a New Hybrid Parallel Robot ManipulatorJournal of Mechanisms and Robotics
Belgacem Bekkar, Khaled Ferkous (2022)
Design of Online Fuzzy Tuning LQR Controller Applied to Rotary Single Inverted Pendulum: Experimental ValidationArabian Journal for Science and Engineering, 48
H. Rabiee, M. Ataei, Mohsen Ekramian (2019)
Continuous nonsingular terminal sliding mode control based on adaptive sliding mode disturbance observer for uncertain nonlinear systemsAutom., 109
Wu Qingxiang, Wang Xiaokai, Lin Hua, Minghui Xia (2020)
Dynamic analysis and time optimal anti-swing control of double pendulum bridge crane with distributed mass beamsMechanical Systems and Signal Processing, 144
Xiangyu Liu, Chunyan Zhang, Cong Ni, Chenhui Lu (2019)
A reconfigurable multi-mode walking-rolling robot based on motor time-sharing controlInd. Robot, 47
Yangyang Dong, Tongle Zhang, Shaojie Han, Yipan Guo, Bo-Yan Zeng, Yongbin Wang, Zijian Zhang (2022)
Spherical robot with spring energy storage type hopping mechanisms: design, dynamics and experimental evaluationInd. Robot, 49
M. Hasan, N. Abbas (2022)
Disturbance Rejection for Underwater robotic vehicle based on adaptive fuzzy with nonlinear PID controller.ISA transactions
Samira Asiri, Farshad Khademianzadeh, A. Monadjemi, P. Moallem (2019)
The Design and Development of a Dynamic Model of a Low-Power Consumption, Two-Pendulum Spherical RobotIEEE/ASME Transactions on Mechatronics, 24
Q. Zhan (2019)
Research Progress and Development Trend of Spherical Mobile RobotsJournal of Mechanical Engineering
Minghe Tian, Bo Wang, Yong Yu, Qinghua Dong, Dianguo Xu (2021)
Discrete-Time Repetitive Control-Based ADRC for Current Loop Disturbances Suppression of PMSM DrivesIEEE Transactions on Industrial Informatics, 18
In complex environments, a spherical robot has great application value. When the pendulum spherical robot is stopped or disturbed, there will be a periodic oscillation. This situation will seriously affect the stability of the spherical robot. Therefore, this paper aims to propose a control method based on backstepping and disturbance observers for oscillation suppression.Design/methodology/approachThis paper analyzes the mechanism of oscillation. The oscillation model of the spherical robot is constructed and the relationship between the oscillation and the internal structure of the sphere is analyzed. Based on the oscillation model, the authors design the oscillation suppression control of the spherical robot using the backstepping method. At the same time, a disturbance observer is added to suppress the disturbance.FindingsIt is found that the control system based on backstepping and disturbance observer is simple and efficient for nonlinear models. Compared with the PID controller commonly used in engineering, this control method has a better control effect.Practical implicationsThe proposed method can provide a reliable and effective stability scheme for spherical robots. The problem of instability in real motion is solved.Originality/valueIn this paper, the oscillation model of a spherical robot is innovatively constructed. Second, a new backstepping control method combined with a disturbance observer for the spherical robot is proposed to suppress the oscillation.
Industrial Robot: An International Journal – Emerald Publishing
Published: Jul 2, 2024
Keywords: Spherical robot; Backstepping method; Oscillation suppression; Disturbance observer
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