Dan Zhang, Qi Zou, Sheng Guo, and Haibo Qu


  1. [1] S.S. Hu, Welding automation technology and application (Beijing: China Machine Press, 2015).
  2. [2] S.B. Chen, On Intelligentized welding manufacturing, in T.J. Tran, S.B. Chen and X.Q. Chen (eds.), Robotic welding, intelligence and automation (Cham: Springer International, 2015), 3–34.
  3. [3] D. Lakov, D. Karastojanov, and G. Nachev, Adaptivity in ARC welding robot control, IFAC Proceedings, 18(16), 1985, 369–371.
  4. [4] I. Mandic, Z. Domazet, and D. Stipanicev, Introduction of welding robots in shipyards, Advanced Robotics, 3(1), 1988, 35–51. 267
  5. [5] Y. Nagao, H. Urabe, F. Honda, et al., Development of a teachingless robot system for welding a large-sized box-type construction, Advanced Robotics, 15(3), 2012, 287–291.
  6. [6] C. Chen, D. He, D. He, et al., An approach to the path planning of tube–sphere intersection welds with the robot dedicated to J-groove joints, Robotics and Computer-Integrated Manufacturing, 29(4), 2013, 41–48.
  7. [7] D. Lee, T. Seo, and J. Kim, Optimal design and workspace analysis of a mobile welding robot with a 3P3R serial manipulator, Robotics & Autonomous System, 59(10), 2011, 813–826.
  8. [8] M.J. Tsai, C.F. Huang, H.R. Hwang, et al., An intelligent reverse engineering and processing educatable robot—ReapeR, Taiwan patent no: 203020, 2003.
  9. [9] P.C. Tung, M.C. Wu, and Y.R. Hwang, An image-guided mobile robotic welding system for SMAW repair processes, International Journal of Machine Tool & Manufacture, 44(11), 2004, 1223–1233.
  10. [10] S. Patel and T. Sobh, Manipulator performance measures – A comprehensive literature survey, Journal of Intelligent & Robotic Systems, 77(3–4), 2015, 547–570.
  11. [11] J.P. Merlet, Jacobian, manipulability, condition number and accuracy of parallel robots, Journal of Mechanical Design, 128(128), 2005, 199–206.
  12. [12] X.Y. Wu, Z.J. Xie, J.A. Kepler, et al., A parametric model of 3-PPR planar parallel manipulators for optimum shape design of platforms, Mechanism & Machine Theory, 118, 2017, 139–153.
  13. [13] X.J. Liu, X. Chen, and M. Nahon, Motion/Force constrainability analysis of lower-mobility parallel manipulators, Journal of Mechanisms & Robotics, 6(3), 2014, 031006-1–031006-9.
  14. [14] M. Russo, S. Herrero, O. Altuazrra, et al., Kinematic analysis and multi-objective optimization of a 3-UPR parallel mechanism for a robotic leg, Mechanism & Machine Theory, 120, 2018, 192–202.
  15. [15] R. Kelaiaia, O. Company, and A. Zaatri, Multiobjective optimization of a linear Delta parallel robot. Mechanism & Machine Theory, 50(2), 2012, 159–178.
  16. [16] J. Yao, W. Gu, Z. Feng, et al., Dynamic analysis and driving force optimization of a 5-DOF parallel manipulator with redundant actuation, Robotics and Computer-Integrated Manufacturing, 48, 2017, 51–58.
  17. [17] Y.J. Zhao, Dynamic performance evaluation of a three translational degrees of freedom parallel robot, International Journal of Robotics and Automation, 27(1), 2012, 31–40.
  18. [18] X.L Shan and G Cheng, Kinematic analysis and parameter optimization for a novel 2(3HUS+S) parallel hip joint simulation, International Journal of Robotics and Automation, 32(4), 2017, 379–386.
  19. [19] M.W. Spong, S. Hutchinson, and M. Vidyasagar, Robot modeling and control (New York: John Wiley & Sons Inc, 2016).
  20. [20] J.J. Craig, Introduction to robotics: mechanics and control (Reading, Mass.: Addison-Wesley Publishing Company, 1986).
  21. [21] L.L. Zhang, Performance analysis and dimension optimization of 2-DOF parallel manipulators. Doctoral dissertation, Yanshang University, Qinhuangdao, China, 2006.

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