Experimental Investigations of the Control Algorithm of a Mobile Manipulation Robot
2019, Vol. 15, no. 4, pp. 487-495
Author(s): Karavaev Y. L., Shestakov V. A., Yefremov K. S.
This paper presents experimental investigations of the control algorithm of a highly maneuverable
mobile manipulation robot. The kinematics of a mobile manipulation robot, the
algorithm of trajectory planning of the mobile robot to the point of object gripping are considered.
By realization of the algorithm, the following tasks are solved: solution of the inverse
positional task for the mobile manipulation robot; motion planning of the mobile manipulator
taking into account the minimization of energy and time consumption per movement. The result
of the algorithm is a movement to the point of gripping of the manipulation object; grasping
and loading of the object. Experimental investigations of the developed algorithms are given.
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References |
|
| [1] |
Aviles, O., Mauricio, F., Mauledoux, M., and Rubiano, O., “Electronic Architecture for a Mobile Manipulator”, International Journal of Online Engineering (iJOE), 14:2 (2018),  |
| [2] |
Röhrig, Ch., Heß, D., and Künemund, F., “Motion Controller Design for a Mecanum Wheeled Mobile Manipulator”, Proc. of the IEEE Conf. on Control Technology and Applications (CCTA, Mauna Lani, Hawaii, USA, 2017), |
| [3] |
Hvilshoj, M. and Bogh, S., Int. J. Adv. Robot. Syst., 8:2 (2011), |
| [4] |
Dömel, A., Kriegel, S., Kaßecker, M., Brucker, M., Bodenmüller, T., and Suppa, M., “Toward Fully Autonomous Mobile Manipulation for Industrial Environments”, Int. J. Adv. Robot. Syst., 14:4 (2017), |
| [5] |
Nieuwenhuisen, M., Droeschel, D., Holz, D., Stückler, J., Berner, A., Li, J., Klein, R., and Behnke, S., “Mobile Bin Picking with an Anthropomorphic Service Robot”, Proc. of the IEEE Internat. Conf. on Robotics and Automation (Karlsruhe, 2013), |
| [6] |
Borisov, A. V., Kilin, A. A., and Mamaev, I. S., “An Omni-Wheel Vehicle on a Plane and a Sphere”, Nelin. Dinam., 7:4 (2011),  |
| [7] |
Kilin, A. A. and Bobykin, A. D., “Control of a Vehicle with Omniwheels on a Plane”, Nelin. Dinam., 10:4 (2014),  |
| [8] |
Kilin, A., Bozek, P., Karavaev, Yu., Klekovkin, A., and Shestakov, V., “Experimental Investigations of a Highly Maneuverable Mobile Omniwheel Robot”, Int. J. Adv. Robot. Syst., 14:6 (2017), |
| [9] |
Karavaev, Yu. L. and Trefilov, S. A., “Deviation Based Discrete Control Algorithm for Omni-Wheeled Mobile Robot”, Nelin. Dinam., 9:2 (2013), |
| [10] |
Karavaev, Yu. and Shestakov, V., “Construction of a Service Area of a Highly Maneuverable Mobile Manipulation Robot”, Intellekt. Sist. v Proizv., 16:3 (2018), |
| [11] | Zenkevich, S. L. and Yushchenko, A. S., Fundamentals of Manipulation Robots, MGTU, Moscow, 2004, 576 pp. (Russian) |
| [12] |
Prokop, J., Richard, P., and Reeves, A., “A Survey of Moment-Based Techniques for Unoccluded Object Representation and Recognition”, CVGIP-Graph. Model. Im., 54:5 (1992), |
| [13] |
Mercimek, M., Gulez, K., and Mumcu, T. V., “Real Object Recognition Using Moment Invariants”, Sadhana, 30:6 (2005),  |
| [14] |
Lachat, E., Macher, H., Mittet, M.-A., Landes, T., and Grussenmeyer, P., “First Experiences with Kinect v2 Sensor for Close Range 3D Modelling”, ISPRS: Internat. Arch. of the Photogrammetry, Remote Sensing and Spatial Information Sciences (2015), v. XL-5/W4, |
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