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Abstract

Multidegree of freedom series robots are used in various fine work scenarios. The redundant DOF (short for degree of freedom) robots have excess degrees of freedom and can easily avoid obstacles, their own singularities, and joint limits. But the dynamics model of redundant DOF robot is complicated, difficult to solve, and slow to calculate. These are not conducive to the monitoring and analysis of the robot's state and parameters. A method of robot dynamics calculation based on wavelet approximation is proposed in this article. First, the robot dynamics model is established based on Lagrange method. Then, a multidimensional analysis model of robot dynamics wavelet approximation is established. Next, a 6-DOF UR5 robot is taken as an object to compare these methods. The six-dimensional wavelet approximation method has high accuracy with a long calculation time. One-dimensional wavelet approximation method has the best performance both in computational efficiency. The higher the degree of freedom of the robot, the greater the advantage of the wavelet analysis method because it does not need to solve the exponential increasing matrix in the dynamics model. In the identification and analysis of robot load and dynamic parameters, one-dimensional wavelet approximation method has the accuracy close to the dynamic model, and the minimum identification error is within 9.04%. The proposed method provides a new technical approach for dynamic modeling and control of high degree of freedom robots.

Keywords

Series robot wavelet approximation dynamic analysis parameters identification high degree of freedom

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References

Baratova

Zhumadillayev

Tolebaev

. Feature of the autonomous robot for cleaning the floor in the bathroom. J Math Mech Comput Sci 2022; 115: 91–100.

Chiaverini

Oriolo

Maciejewski

. Redundant robots. In: Siciliano

Khatib

(eds) Springer handbook of robotics. 2nd ed. Berlin: Springer, 2016, pp. 221–242.

Riva

Cravero

Briguglio

, et al. The flex robotic system in head and neck surgery: a review. Cancers (Basel) 2022; 14: 5541.

Mattheis

Hasskamp

Holtmann

, et al. Flex robotic system in transoral robotic surgery: the first 40 patients. Head Neck 2017; 39: 471–475.

Luo

. An overview of calibration technology of industrial robots. IEEE/CAA J Autom Sin 2021; 8: 23–36.

Meng

Xiaobo

Shunliang

, et al. Multiple stability analysis of gait in arc-foot passive walking robots. Acta Mech Sin 2024; 56: 1784–1795.

Raviola

, et al. Effects of temperature and mounting configuration on the dynamic parameters identification of industrial robots. Robotics 2021; 10: 83.

Farsoni

Ferraguti

Bonfè

. Safety-oriented robot payload identification using collision-free path planning and decoupling motions. Robot Comput Integr Manuf 2019; 59: 189–200.

Fan

Chen

, et al. Dynamic identification of the KUKA LBR IIWA robot with retrieval of physical parameters using global optimization. IEEE Access 2020; 8: 108018–108031.

10.

Qian

Chen

, et al. Solving method for dynamic equations of mechanical multibody system by using bathe integration algorithm. J Shanghai Jiao Tong Univ 2020; 54: 1218–1226.

11.

Ding

. Multistep block method for constrained Hamilton's equations of multibody system dynamics. Chin J Appl Mech 2021; 38: 1016–1021.

12.

Zhu

Pan

Wang

, et al. Modeling of dynamic-elastic deformation error for a collaborative robot. In: 2023 IEEE 18th Conference on Industrial Electronics and Applications (ICIEA), 18–20 August 2023, pp. 1345–1350. Ningbo, China: IEEE.

13.

Xiao

Wang

, et al. Joint torque prediction of industrial robots based on PSO-LSTM deep learning. Ind Robot Int J Robot Res Appl 2024; 51: 501–510.

14.

Huang

Lin

Liu

, et al. Velocity-aware spatial-temporal attention LSTM model for inverse dynamic model learning of manipulators. Front Neurorobot 2024; 18: 1353879.

15.

Zhou

Fang

. Advances in dynamics of modular reconfigurable robots. J Dyn Control 2023; 21: 1–17.

16.

Nainer

Feder

Giusti

, et al. Automatic generation of kinematics and dynamics model descriptions for modular reconfigurable robot manipulators. In: 2021 IEEE 17th International Conference on Automation Science and Engineering (CASE), 23–27 August 2021, pp. 45–52. Lyon, France: IEEE.

17.

Whitman

Travers

Choset

. Learning modular robot control policies. IEEE Trans Robot 2023; 39: 4095–4113.

18.

Liu

Zhou

Wang

. Research progresses of wavelet methods and their applications in mechanics. Appl Math Mech 2022; 43: 1–13.

19.

Wang

Zhou

. Wavelet solutions of a class of quasi-linear equations. J Lanzhou Univ (Nat Sci) 2019; 055: 233–240.

20.

Liu

Wang

, et al. A wavelet multi-resolution enabled interpolation Galerkin method for two-dimensional solids. Eng Anal Boundary Elem 2020; 117: 251–268.

21.

Liu

Wang

, et al. A wavelet multiresolution interpolation Galerkin method with effective treatments for discontinuity for crack growth analyses. Eng Fract Mech 2020; 225: 106836.

22.

Feng

Wang

Liu

, et al. A wavelet method for large-deflection bending of irregular plates. Int J Mech Sci 2023; 252: 108358.

23.

Dixit

Dhende

, et al. Dynamic analysis of a novel modular robot. In: Sharma

Saraswat

Yadav

, et al. (eds) Congress on Intelligent Systems (CIS 2021), 4–5 September 2021, pp. 775–787. Springer: Virtual Conference.

24.

Guo

Zhang

Lim

, et al. A review of wavelet analysis and its applications: challenges and opportunities. IEEE Access 2022; 10: 58869–58890.

25.

Zhou

Wang

. Generalized Gaussian integral method for calculations of scaling function transform of wavelets and its applications. Acta Math Sci A 1999; 19: 293–299.

26.

Zhou

Wavelet numerical method and its applications in nonlinear problems. Singapore: Springer, 2021, pp. 1–469.

27.

Duo

Fan

. On wavelets and prewavelets with vanishing moments in higher dimensions. J Approx Theory 1997; 90: 46–74.

28.

Wang

Zhou

. Error estimation of generalized wavelet Gaussian integral method. J Lanzhou Univ 1998; 02: 30–34.

29.

Nigam

Mohapatra

Murari

. Wavelet approximation of a function using Chebyshev wavelets. J Inequal Appl 2020; 01: 187.

30.

Liu

Zhang

Jia

. A compressive super-resolution framework based on low-rank tensor approximation and adaptive one-dimensional wavelet approximation. IEEE Trans Image Process 2021; 30: 7750–7764.

31.

Kufieta

. Force estimation in robotic manipulators: Modeling, simulation and experiments. Trondheim: Norwegian University of Science and Technology, 2014.

A wavelet approximation method for dynamic analysis and parameters identification of series robot with high degree of freedom

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