A dynamic modeling and control method is presented based on virtual simulation to achieve force-feedback operation of complicated haptic device with parallel structure. Firstly, the Maryland haptic device is analyzed and its mathematic model is established. And, a physical simulation model is built in SimMechanics environment, which can be amended and compensated directly according to the experimental environment and the calibration parameters. The driving results of the two models are contrasted, and the result shows that the revised simulation model has higher precision and can be used for dynamic control. Finally, a semi-physical simulation system is established according to control requirements, after designing the collision simulation module on the basis of the simulation model. And the experiment is accomplished about generating horizontal feedback force according to collision sign in operation process. The haptic device forces in the simulation and the experiment are consistent, which shows the feasibility and accuracy of the control method.
[1] 邓乐,赵丁选,唐新星.具有力觉临场感的遥操作操纵器关键技术研究[J].工程设计学报,2005,12(3):160-161. Deng L, Zhao D X, Tang X X. Research on key technologies of controller for teleoperation force reflecting telepresence[J]. Journal of Engineering Design, 2005, 12(3): 160-161.[2] 陆熊,宋爱国.力/触觉再现设备的研究现状与应用[J].测控技术,2008,27(8):6-10. Lu X, Song A G. Recent developments of haptic device and its applications[J]. Measurement & Control Technology, 2008, 27(8): 6-10.[3] Arata J, Lkedo N, Fujimoto H. Force producibility improvement of redundant parallel mechanism for haptic applications[C]//IEEE/RSJ International Conference on Intelligent Robots and Systems. Piscataway, USA: IEEE, 2011: 2145-2150.[4] Chaker A, Laribi M A, Zeghloul S, et al. Design and optimization of spherical parallel manipulator as a haptic medical device[C]//37th Annual Conference on IEEE Industrial Electronics Society. Piscataway, USA: IEEE, 2011: 80-85.[5] Li Y, Yan Z Y, Wang H M, et al. Design and optimization of a haptic manipulator using series-parallel mechanism[C]//IEEE International Conference on Mechatronics and Automation. Piscataway, USA: IEEE, 2012: 2140-2145.[6] Yoon W K, Suehiro T, Tsumaki Y, et al. A compact modified Delta parallel mechanism design based on a stiffness analysis[C]//IEEE/ASME International Conference on Advanced Intelligent Mechatronics. Piscatway, USA: IEEE, 2003: 1262- 1267.[7] Taniguchi Y, Tsumugiwa T, Yokogawa R. Development of force haptic device equipped with 3-DOF parallel mechanism[J]. Transactions of the Japan Society of Mechanical Engineers: Series C, 2012, 78(793): 3228-3238. [8] Kim H W, Lee J H, Suh I H, et al. Comparative study and experimental verification of singular-free algorithms for a 6 DOF parallel haptic device[J]. Mechatronics, 2005, 15(4): 403-422. [9] Chen C, HeyneWJ, Jackson D. A new 6-DOF 3-legged parallel mechanism for force-feedback interface[C]//IEEE/ASME International Conference on Mechatronics and Embedded Systems and Applications. Piscataway, USA: IEEE, 2010: 539-544.[10] Tsai LW,Walsh G C, Stamper R E. Kinematics of a novel three DOF translational platform[C]//IEEE International Conference on Robotics and Automation. Piscataway, USA: IEEE, 1996: 3446-3451.[11] Tsai L W. Robot analysis: The mechanics of serial and parallel manipulators[M]. Hoboken, USA: John Wiley & Sons Inc., 1999: 447-451.
