DESIGN AND IMPLEMENTATION OF NONLINEAR PID CONTROLLER FOR A QUADROTOR CONTROL

Authors

  • O. Medjdoubi Laboratoire Commande, Analyse et Optimisation des Systèmes Electro-Energétiques, Université de Bechar, Algérie
  • A. Hazzab Laboratoire Commande, Analyse et Optimisation des Systèmes Electro-Energétiques, Université de Bechar, Algérie
  • A. Alalei Laboratoire Commande, Analyse et Optimisation des Systèmes Electro-Energétiques, Université de Bechar, Algérie

DOI:

https://doi.org/10.4314/jfas.v11i1.35

Keywords:

PID Controller; Reference Model; Nonlinear system; Quadcopter

Abstract

The following article represents the control of an unmanned airborne vehicle (Quadcopter), using nonlinear PID controllers in order to control the altitude, as well as the attitudes (pitch, roll and yaw) of the Quadcopter. Two approaches have been proposed for adjusting the parameters of a PID controller. Foremost, the PID controller gains are settled in an ideal way by using a reference model strategy. In the moment approach, these parameters are adjusted Nonlinear PID. MATLAB/Simulink has been utilized to test and compare the execution of the controllers gotten. The obtained results using the nonlinear PID controllers show the efficiency of the proposed controllers it present a response with less error and minimal over shoot compared to the results of classical PID controller.

Downloads

Download data is not yet available.

References

[1] H. Khebbache and M. Tadjine, “Robust Fuzzy Backstepping Sliding Mode Controller For a Quadrotor,” CEAI vol. 15, no. 2, pp. 3–11, 2013.
[2] S. Kumar N and R. Kishore “Design and control implementation of quadcopter” International Journal of Mechanical And Production Engineering, ISSN: 2320-2092, pp. 69-72, 2017.
[3] Muhammad Arifudin Lukmana “Preliminary Study on Unmanned Aerial Vehicle (UAV) Quadcopter Using PID Controller.
[4] S. Bouabdallah, A. Noth, and R. Siegwan, “PID vs LQ Control Techniques Applied to an Indoor Micro Quadrotor” in Proc. (IEEE) International Conference on Intelligent Robots (IROS’04), (Sendai, Japan), pp. 2451–2456, 2004.
[5] B. Erginer, “Modeling and PD Control of a Quadrotor VTOL Vehicle,” Proceedings of the 2007 IEEE Intelligent Vehicles Symposium Istanbul, Turkey, June 13-15, pp. 894–899, 2007.
[6] B. Erginer and E. Altuğ, “Design and Implementation of a Hybrid Fuzzy Logic Controller for a Quadrotor VTOL Vehicle,” International Journal of Control, Automation, and Systems, vol. 10, pp. 61–70, 2012.
[7] A. Laoufil, A. Hazzab, I. K. Bousserhane, “Direct Field-Oriented Control using Backstepping Technique for Induction Motor Speed Control” 0-7803-9521-2/062006 IEEE.
[8] A. Hazzab and I.K. Bousserhane, “Real Time Implementation of Fuzzy Gain Scheduling of PI Controller for Induction Machine Control” 0-7803-9521-2/06/2006.
[9] A. Sharma and P. A. Barve, “Controlling of Quad-rotor UAV Using PID Controller and Fuzzy Logic Controller,” International Journal of Electrical, Electronics and Computer Engineering,vol. 1, no. 2,pp.38- 41,2012.
[10] H. Boudjedir, O. Bouhali, and N. Rizoug, “Adaptive neural network control based on neural observer for quadrotor unmanned aerial vehicle,” Advanced Robotics, vol. 28, no. 17, pp. 1151–1164, 2014.
[11] I. Siti and M.Mjahed “Control of a Quadcopter using Reference Model and Genetic Algorithm Methods” 978-1-4673-9669-1/15 IEEE 2015.
[12] Fouad Mokhtar “Decentralized Nonlinear Control Strategies for Disturbance Rejection in Winding Systems” IEEE International Electric Machines & Drives Conference (IEMDC) 2011.

Downloads

Published

2018-12-28

How to Cite

MEDJDOUBI, O.; HAZZAB, A.; ALALEI, A. DESIGN AND IMPLEMENTATION OF NONLINEAR PID CONTROLLER FOR A QUADROTOR CONTROL. Journal of Fundamental and Applied Sciences, [S. l.], v. 11, n. 1, p. 548–561, 2018. DOI: 10.4314/jfas.v11i1.35. Disponível em: https://jfas.info/index.php/JFAS/article/view/237. Acesso em: 29 jan. 2025.

Issue

Vol. 11 No. 1 (2019)

Section

Articles