Implementation and Analysis of Motion Control Techniques on an Industrial 7 DOF Robotic Manipulator

Main Article Content

Syed Huzaifa Ali
Ehtisham Ul Hassan

Abstract

With the quest for modernization in robotics motion control of robot manipulators is an area of active research. In motion control, inverse trajectory application is the most adopted solution which is further improved by considering the effect of external forces of the environment. The impact of external force involves dynamic modelling of the system and force control, impedance control, and admittance control techniques are adopted for the solution. This research implements the simulation and more precise visualization of the real-life manipulator under the rules of kinematics and dynamics on a 7 Degree of Freedom manipulator. The objective of this research is to implement motion control techniques: Forward Kinematics, Inverse kinematics, and Trajectory tracking using MATLAB Robotic System Toolbox and analyze the results obtained. These simulations can an effective tools for tuning the motion of robotics by varying the control parameter in simulation and then implementing them in physical hardware.

Article Details

How to Cite
Ali, S. H., & Ul Hassan, . E. (2022). Implementation and Analysis of Motion Control Techniques on an Industrial 7 DOF Robotic Manipulator. Journal of Studies in Science and Engineering, 2(2), 33–43. https://doi.org/10.53898/josse2022223
Section
Research Articles

References

Barinka, L. and Berka, R., 2002. Inverse kinematics-basic methods. Czech Technical University, pp.1-10.

Pertuz, S.A., Llanos, C.H., & Muñoz, D. (2017). Simulation and implementation of impedance control in robotic hand. In 24th ABCM international congress of mechanical engineering (pp. 1–10). ABCM, Curitiba.

D'Souza, A., Vijayakumar, S. and Schaal, S., 2001, October. Learning inverse kinematics. In Proceedings 2001 IEEE/RSJ International Conference on Intelligent Robots and Systems. Expanding the Societal Role of Robotics in the the Next Millennium (Cat. No. 01CH37180) , IEEE, 1:298-303.

. Neville, H., 1985. Impedance Control: An Approach to Manipulation: Part I~ III. Trans. of ASME Journal of Dynamic System, Measurement, and Control, 107, p.1.

Hogan, N., 1984, June. Impedance control: An approach to manipulation. In 1984 American control conference (pp. 304-313). IEEE.

Hernandez-Barragan, J., Lopez-Franco, C., Antonio Gopar, C., Alanis, A.Y. and Arana-Daniel, N., 2018, November. The inverse kinematics solutions for robot manipulators based on firefly algorithm. In 2018 IEEE Latin American Conference on Computational Intelligence (LA-CCI) (pp. 1-5). IEEE.

Benotsmane, R., Kovács, G. and Dudás, L., 2019. Economic, social impacts and operation of smart factories in In-dustry 4.0 focusing on simulation and artificial intelligence of collaborating robots. Social Sciences, 8(5), p.143.

Bertram, D., Kuffner, J., Dillmann, R. and Asfour, T., 2006, May. An integrated approach to inverse kinematics and path planning for redundant manipulators. In Proceedings 2006 IEEE International Conference on Robotics and Automation, 2006. ICRA 2006. (pp. 1874-1879). IEEE.

Song, P., Yu, Y. and Zhang, X., 2017, July. Impedance control of robots: an overview. In 2017 2nd international conference on cybernetics, robotics and control (CRC) (pp. 51-55). IEEE.

Lu, W.S. and Meng, Q.H., 1991. Impedance control with adaptation for robotic manipulations. IEEE Transactions on Robotics and Automation, 7(3), pp.408-415.

Yoshikawa, T., 2000, April. Force control of robot manipulators. In Proceedings 2000 ICRA. Millennium Conference. IEEE International Conference on Robotics and Automation. Symposia Proceedings (Cat. No. 00CH37065) (Vol. 1, pp. 220-226). IEEE.

Faraj, B.M. and Ahmed, F.W., 2019. On the Matlab technique by using Laplace transform for solving second order ode with initial conditions exactly. Matrix Science Mathematic, 3(2), pp.08-10.

de Gea, J. and Kirchner, F., 2008. Modelling and simulation of robot arm interaction forces using impedance control. IFAC Proceedings Volumes, 41(2), pp.15589-15594.

Whitney, D.E., 1987. Historical perspective and state of the art in robot force control. The International Journal of Robotics Research, 6(1), pp.3-14.