INVERSE KINEMATIC SOLUTION OF A 7-DOF ROBOT WITH A TELESCOPIC FOREARM BASED ON JOINT LIMIT AND INERTIA MATRIX FLUCTUATION

Yutian Wang, Jiahao Qiu, Jun Wu, and Jinsong Wang,

References

  1. [1] J. Wu, B. Zhang, L. Wang, and G. Yu, An iterative learning method for realizing accurate dynamic feedforward control of an industrial hybrid robot, Science China Technological Sciences, 64(6), 2021, 1177–1188.
  2. [2] Z.-Y. Li, D.-J. Zhao, and J.-S. Zhao, Structure synthesis and workspace analysis of a telescopic spraying robot, Mechanism and Machine Theory, 133, 2019, 295–310.
  3. [3] R.-J. Guo and J.-S. Zhao, Topological principle of strengthened connecting frames in the stretchable arm of an industry coating robot, Mechanism and Machine Theory, 114, 2017, 38–59.
  4. [4] J. Wu, H. Ye, G. Yu, and T. Huang, A novel dynamic evaluation method and its application to a 4-DOF parallel manipulator, Mechanism and Machine Theory, 168, 2022, 104627.
  5. [5] D. Zhang, Q. Zou, S. Guo, and H.B. Qu, Kinematics and performances analysis of a novel hybrid welding robot, International Journal of Robotics & Automation, 35(4), 2020, 261–268.
  6. [6] G. Kanagaraj, S.A.R.S. Masthan, and V.F. Yu, Inverse kinematic solution of obstacle avoidance redundant robot manipulator by bat algorithms, International Journal of Robotics & Automation, 36(1), 2021, 18–26.
  7. [7] M. Madhu, S.P. Kumar, S. Shriram, and R. Vignesh, A CCD-based inverse kinematics approach using Frenet-Serret parameterization for SHR manipulators, International Journal of Robotics & Automation, 36(3), 2021, 140–147. 9
  8. [8] J. Choi, K. Kim, and H.Y. Kim, Kinetics and multibody dynamics simulation of parallel delta robot, International Journal of Robotics & Automation, 36(5), 2021, 292–303.
  9. [9] Y.-L. Lai, C.-C. Liao, Z.-G. Chao, Inverse kinematics for a novel hybrid parallel serial five-axis machine tool, Robotics and Computer-Integrated Manufacturing, 50, 2018, 63–79.
  10. [10] J. Wu, J. Wang, and Z. You, An overview of dynamic parameter identification of robots, Robotics and Computer-Integrated Manufacturing, 26(5), 2010, 414–419.
  11. [11] G.K. Singh and J. Claassens, An analytical solution for the inverse kinematics of a redundant 7-DoF manipulator with link offsets, IEEE/RSJ 2010 International Conference on Intelligent Robots and Systems (IROS 2010), 2010, 2976–2982.
  12. [12] M.V. Weghe, D. Ferguson, and S.S. Srinivasa, Randomized path planning for redundant manipulators without inverse kinematics, 7th IEEE-RAS International Conference on Humanoid Robots, 2007, 477–482.
  13. [13] D. Berenson, S.S. Srinivasa, D. Ferguson, A. Collet, and J. J. Kuffner, Manipulation planning with workspace goal regions, ICRA: 2009 IEEE International Conference on Robotics and Automation, 2009, 1397–1403.
  14. [14] M. Crenganis, M. Tera, C. Biris, and C. Girjob, Dynamic analysis of a 7 DOF robot using fuzzy logic for inverse kinematics problem, 7th International Conference on Information Technology and Quantitative Management, 2019, 298–306.
  15. [15] C. Faria, F. Ferreira, W. Erlhagen, S. Monteiro, and E. Bicho, Position-based kinematics for 7-DoF serial manipulators with global configuration control, joint limit and singularity avoidance, Mechanism and Machine Theory, 121, 2018, 317– 334.
  16. [16] P. Dahm and F. Joublin, Closed form solution for the inverse kinematics of a redundant robot arm, Computer Aided Geometric Design, 2016, 163–171.
  17. [17] H. Moradi and S. Lee, Joint limit analysis and elbow movement minimization for redundant manipulators using closed form method, International Conference on Intelligent Computing, 2005, 423–432.
  18. [18] J. Wang, Y. Li, and X. Zhao, Inverse kinematics and control of a 7-dof redundant manipulator based on the closed-loop algorithm, International Journal of Advanced Robotic Systems, 7(4), 2010, 1–9.
  19. [19] W.W. Gan and S. Pellegrino, Numerical approach to the kinematic analysis of deployable structures forming a closed loop, Proceedings of the Institution of Mechanical Engineers Part C-Journal of Mechanical Engineering Science, 220(7), 2006, 1045–1056.
  20. [20] S. Kucuk and Z. Bingul, The inverse kinematics solutions of fundamental robot manipulators with offset wrist, IEEE International Conference on Mechatronics (ICM), 2005, 197– 202.
  21. [21] J. Zhao, T. Xu, Q. Fang, Y. Xie, and Y. Zhu, A synthetic inverse kinematic algorithm for 7-DOF redundant manipulator, Proceedings of 2018 IEEE International Conference on RealTime Computing and Robotics (IEEE RCAR), 2018, 112–117.
  22. [22] R.V. Dubey, J.A. Euler, and S.M. Babcock, An efficient gradient projection optimization scheme for a seven-degreeof-freedom redundant robot with spherical wrist, Proceedings of the 1988 IEEE International Conference on Robotics and Automation (CAT. No.88CH2555-1), 1988, 1, 28–36.
  23. [23] O. Khatib, Inertial properties in robotic manipulation: an object-level framework, The International Journal of Robotics Research, 13(1), 1995, 13–36.
  24. [24] S. Tadokoro, I. Kimura, and T. Takamori, A measure for evaluation of dynamic dexterity based on a stochastic interpretation of manipulator motion, Fifth International Conference on Advanced Robotics, Pisa, Italy, 1991, 509–514.
  25. [25] K. Hu, J. Zhang, Y. Dong, and D. Wu, Inverse kinematic optimization for 7-DoF serial manipulators with joint limits, J. Tsinghua Univ. (Sci. & Technol.), 60(12), 2020, 1007–1015.

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