Skip to main navigation menu Skip to main content Skip to site footer
International Journal of Robotics and Automation Technology

Articles

Vol. 11 (2024)

Dynamics Modelling and Adaptive Identification: Towards Improved Human-Robot Interaction in Collaborative Systems

DOI
https://doi.org/10.31875/2409-9694.2024.11.09
Submitted
November 24, 2024
Published
23.11.2024

Abstract

This article presents a novel approach to enhancing human-robot collaboration and safety through advanced dynamic modelling and adaptive identification techniques. We introduce a comprehensive methodology that integrates motion trajectory design with real-time torque detection, addressing the critical limitations of conventional systems that rely on costly joint torque sensors. By simultaneously identifying friction forces in an integrated joint and a simplified two-bar mechanism, our approach leverages existing kinematic and dynamic models to achieve precise dynamic parameter identification. The proposed method significantly advances the fields of drag-teaching and collision detection by eliminating the need for force sensors, thus making it more feasible for mass-produced robotic systems. Our findings demonstrate that accurate dynamic modelling is essential for effective zero-force control, particularly in high-speed drag-teaching scenarios, where inertia and friction present substantial challenges. Experimental validation confirms the efficacy of our dynamic feed-forward controller design and the adaptability of drag-teaching parameters, leading to improved operational flexibility and safety in collaborative environments. This research contributes a critical framework for future developments in intelligent robotic systems, providing a robust basis for integrating advanced human-robot interactions in industrial applications.

References

  1. Han Yon. Research on collaborative robot model identification method and human-computer interaction control technology [D]. Shanghai Jiaotong University 2020; 3-5.
  2. Fang Junwei, Wang Binrui, Xie Shenglong, Ren Haijun. Industrial robot dynamics parameter distribution identification and zero-force control teaching [J]. Mechanical Design and Manufacturing. 2021.
  3. Chen Saixuan. Research on zero-force control and collision detection technology of collaborative robots [D]. University of Science and Technology of China 2018; 61-63.
  4. Zhang Tie, Liang Xiaohong, Qin Binbin, Liu Xiaogang. SCARA robot dynamics parameter identification based on Newton's Euler method [J]. Journal of South China University of Technology, 2017; 45(10): 129-130.
  5. Jidong Jia, Minglu Zhang, Changle Li, Chunyao Gao, Xiezhe Zhang, Jie Zhao. Improved dynamic parameter identification method relying on proprioception for manipulators [J]. Nonlinear Dynamics. 2021; 1-16.
  6. Sun Jing, Han xueyan, Li Tong, Li Shihua. Dynamic Parameter Identification of a Pointing Mechanism Considering the Joint Clearance [J]. Robotics 2021; 10(1): 36. https://doi.org/10.3390/robotics10010036
  7. Pan Bingwei, Lv Yan, Jiang Jinfeng, Xue Peijiao. Research on the dynamic parameter identification method of collaborative robots [A]. Shanghai Electric Technology 2019; 12(4): 1-2.
  8. Claudio Urrea, Jose Pascal. Design and validation of a dynamic parameter identification model for industrial manipulator robots [J]. Archive of Applied Mechanics. 2021; 1-27. https://doi.org/10.1007/s00419-020-01865-2
  9. Li Yongquan, Wu Pengtao, Zhang Yang, Zhang Lijie. Dynamic parameter identification and control of spherical two-degree-of-freedom redundant drive parallel robot system [J]. China Mechanical Engineering 2019; 30(16): 1967-1968.
  10. Armstrong. B, Khatib O, Burdick J. The explicit dynamic model and inertial parameters of the PUMA 560 arm [C]. Proceedings of 1986 IEEE International Conference on Robotics and Automation. San Francisco, CA, USA: IEEE, 1986; 510-518. https://doi.org/10.1109/ROBOT.1986.1087644
  11. Chan S P. An efficient algorithm for identification of robot parameters including drive characteristics [J]. Journal of Intelligent and Robotic Systems, 2001; 32(3): 291-305. https://doi.org/10.1023/A:1013918927148
  12. Sousa C. Dynamic model identification of robot manipulators: solving the physical feasibility problem [D]. Coimbra: University of Coimbra, 2014.
  13. Wu Zhiyun, Fu Limin. Finite element algorithm of inertial parameters of robot operator[J]. Journal of Inner Mongolia University of Technology 1995; 14(3): 7-11.
  14. Zhang Shiyuan, Dai Jun, Deng Hua. Dynamic parameter identification of a six-degree-of-freedom robotic arm[A]. Manufacturing Automation 2021; 43(3): 36-37.
  15. Cai Zixing. Robotics [A]. Beijing: Tsinghua University Press, 2009; 73-75.
  16. Arun Banerjee. Flexible Multibody Dynamics: Algorithms Based on Kane’s Method [B]. CRC press.2022. https://doi.org/10.1201/9781003231523
  17. Saixuan Chen, Jie Yang1, Guohua Cui, Fuzhou Niu, Baiqiang Yao and Yu Zhang. Robot Zero-Moment Control Algorithm Based on Parameter Identification of Low-Speed Dynamic Balance [J]. Computer Modeling in Engineering & Sciences 2023; 134(3): 2021-2038. https://doi.org/10.32604/cmes.2022.022669