The Method of Formation the Reference Speed of Movement of the Working Tool of Multilink Manipulator

The solution of task of increasing the productivity of robotic systems containing multilink manipulators is presented in this paper. Their actuators have power limitations. To solve this task, a method has been developed for automatic formation of extremely high reference speeds of their working tools. This method allows to maintain a set dynamic control accuracy, taking into account interactions between all degrees of freedom of these manipulators and restrictions on input signals of their electric drives. The created method consists in calculating the maximum allowable speed of the working tool of the manipulator. The main feature of the method is conditions for selecting required data for quick calculation of all necessary control parameters. A system for forming the speed of the working tool of the manipulator with three rotational degrees of freedom was synthesized based on the proposed method. These degrees of freedom are driven by DC motors. This manipulator can move working tools along arbitrary smooth spatial trajectories formed using third-order parametric splines. The performed simulation confirmed the high efficiency of the proposed method in comparison with other known methods for forming the reference speed. This method provides significant increasing of the reference speed of the working tools due to continuous operation of at least one of the manipulator electric drives near the saturation zone of its power amplifier without entering it. At the same time, the system speed was increased without reducing dynamic accuracy. The created method can be used to generate the extremely high reference speed of the working tools of manipulators with any kinematic schemes and various numbers of degrees of freedom.

1. Filaretov V. F., Zuev A. V., Gubankov A. S. Manipulator control during various technological operations, Moscow, Nauka, 2018, 232 p. (in Russian).

2. Zenkevich S. L., Yushchenko A. S. Robot control. Fundamentals of manipulating robot control, Moscow, Bauman MSTU Publ., 2000, 400 p. (in Russian).

3. Valente A., Baraldo S., Carpanzano E. Smooth trajectory generation for industrial robots performing high precision assembly processes, CIRP Annals — Manufacturing Technology, 2017, vol. 66, no. 1, pp. 17—20.

4. Besset P., Bearee R. FIR filter-based online jerk-constrained trajectory generation, Control Engineering Practice, 2017, vol. 66, pp. 169—180.

5. Haschke R., Weitnauer E., Ritter H. On-Line planning of time-optimal, jerk-limited trajectories, IEEE/RSJ International Conference on Intelligent Robots and Systems, 2008, pp. 3248—3253.

6. Shen P., Zhang X., Fang Y. Real-time acceleration-continuous path-constrained trajectory planning with built-in tradability between cruise and time-optimal motions, ArXiv, 2018, pp. 1—12.

7. Shomlo Ja., Poduraev Ju. V., Lukanin B. C., Sokolov A. G. Automatic planning and control of contour movements of manipulating robots, Mekhatronika, Avtomatizatsiya, Upravlenie, 2001, no. 3, pp. 28—33 (in Russian).

8. Bobrow J. E., Dubowsky S., Gibson J. S. Time-optimal control of robotic manipulators along specified paths, The International Journal of Robotics Research, 1985, vol. 4, no. 3, pp. 3—17.

9. Soon Y. J., Yun J. Ch., PooGyeon P., Seung G. Ch. Jerk limited velocity profile generation for high speed industrial robot trajectories, IFAC Proceedings Volumes, 2005, vol. 38, no. 1, pp. 595—600.

10. Korenchenkov А. А. Time-optimal path control algorithm synthesis of robotic manipulators, Izvestiya KBNC RAN, 2011, vol. 39, no. 1, pp. 142—147 (in Russian).

11. Chudinov V. A., Brudanov A. M. Optimization of trajectories robotic manipulator using dynamic programming, International Scientific Journal, 2016, no. 7, pp. 133—136 (in Russian).

12. Filaretov V. F., Yukhimets D. A., Konoplin A. Yu. Method of synthesis of system of automatic control of manipulator’s gripper movement mode on difficult spatial trajectories, Mekhatronika, Avtomatizatsiya, Upravlenie, 2012, no. 6, pp. 47—54 (in Russian).

13. Filaretov V. F., Gubankov A. S. Formation of extremely high-speed motion of the effector of a multi-joint manipulator by arbitrary trajectory, Informacionno-izmeritel’nye i upravlyayushchie sistemy, 2013, vol. 11, no. 4, pp. 19—25 (in Russian).

14. Rogers D. F., Adams J. A. Mathematical elements for computer graphics, McGraw-Hill, 1976, 239 p.

15. Filaretov V. F., Gubankov A. S., Gornostaev I. V. The formation of motion laws for mechatronics objects along the paths with the desired speed, Proc. of International Conference on Computer, Control, Informatics and Its Applications, Jakarta, Indonesia, 2016, pp. 93—96.