Modeling and simulation of a quadrotor through the integration of Simulink and Solidworks

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Fabio Alfonso Gonzalez
M. E. Afanador Cristancho
E. F. Niño López

Abstract

The current research paper presents the dynamic model from a UAV (Unmanned Aerial Vehicle) type quadcopter. The mentioned model simulates the closest behavior concerning an actual performance when it realizes basic movements. To develop the math model, the quadcopter has been considered a rigid object with 6 DOF (six degrees of freedom) divided into translational and rotational coordinates, using a technique based on Euler-Lagrange Equations to model. In that way, the expressed transfer function on the quadcopter dynamic model can be acquired. The UAV’s rotational dynamic is defined by the most critical inertia moments in the vehicle center of mass, and the inertia moments were estimated using Solidworks software. To achieve it, the quadcopter was assembled with a minimum quantity of parts; after that, the design was uploaded into Simulink software to complete the results, including a 3d animation. A Control Strategy was attached to the quadcopter design to stabilize the described plants. Finally, the performance was corroborated by applying external perturbations like gusts of wind and variable masses, looking to create instability during the flight, expecting a system-controlled reaction. The results showed the UAV stabilized to its reference position in less than twelve seconds (12) against a gust of wind that caused its horizontal displacement. This is an essential application of the rotational dynamics of the UAV, using Simulink and the Simscape Multibody library in conjunction with Solidworks. Achieving a tool of great interest and, therefore, a significant contribution to the study of UAVs, giving the possibility of using a practical tool to design quadrotors focused on different applications, such as precision agriculture.

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Modeling and simulation of a quadrotor through the integration of Simulink and Solidworks. (2018). MASKAY, 9(1), 15-24. https://doi.org/10.24133/maskay.v9i1.1043
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TECHNICAL PAPERS

How to Cite

Modeling and simulation of a quadrotor through the integration of Simulink and Solidworks. (2018). MASKAY, 9(1), 15-24. https://doi.org/10.24133/maskay.v9i1.1043

References

[1] D. Melero Cazorla, “Modelado dinámico y diseño de estrategia de control mediante estimadores para el vuelo autónomo de un quadrotor.,” Universitas Akmeriensis In Lumine Sapientia, 2012.

[2] A. Rincón, V., Molina, A., Torres-León, J.L. y Herazo, “Perspectivas de la tecnología VANT en el cultivo de palma de aceite: monitorización del cultivo mediante imágenes aéreas de alta resolución,” Palmas, vol. 36, no. 3, pp. 25–41, 2015.

[3] P. Castillo, P. García, R. Lozano, and P. Albertos, “Modelado y estabilización de un helicóptero con cuatro rotores,” Rev. Iberoam. Automática e Informática Ind. RIAI, vol. 4, no. 1, pp. 41–57, 2007.

[4] G. De la Cal Mendoza, “Modelado, simulación, construcción y control de un Quadcopter,” Universitat Politècnica de Catalunya, 2014.

[5] V. G. O. Padilla and P. R. P. Arévalo, “Diseño y construcción de un cuadricóptero a control remoto,” Univ. las Fuerzas Armadas ESPE, Carrera Ing. Mecatrónica, p. 12, 2012.

[6] M. Nguyen Duc, T. N. Trong, and Y. S. Xuan, “The quadrotor MAV system using PID control,” 2015 IEEE Int. Conf. Mechatronics Autom. ICMA 2015, pp. 506–510, 2015.

[7] L. M. Ariza Paez, “Modelado matemático de la dinámica de un quadroptero usando Matlab,” Unidades Tecnológicas de Santander, 2013.
[8] G. V. Raffo, “Modelado y control de un helicóptero quadrotor,” Universidad de Sevilla, 2007.

[9] T. Luukkonen, “Modelling and Ccontrol of Quadcopter,” J. Am. Soc. Mass Spectrom., vol. 22, no. 7, pp. 1134–45, 2011.

[10] A. Barrientos, L. F. Peñin, C. Balaguer, and R. Aracil, Fundamentos de Robotica.pdf, Segunda. Madrid, 1996.

[11] P. E. Garrigós, M. S. Maestro, and I. Z. López, Mecánica Clásica. Mdrid: Uned, 2016.

[12] J. J. Craig, Robótica, Tercera ed., vol. 1, no. 8020. Mexico: PEARSON, 2006.

[13] Y. Naidoo, R. Stopforth, and G. Bright, “Quad-Rotor Unmanned Aerial Vehicle Helicopter Modelling & Control Regular Paper,” vol. 8, pp. 139–149, 2011.

[14] T. Bresciani, “Modelling , Identification and Control of a Quadrotor Helicopter,” vol. 4, no. October, p. 213, 2008.

[15] Q. Quan, Introduction to Multicopter Design and Control. Beijing: Springer, 2017.

[16] H. C. T. E. Fernando, A. T. A. De Silva, M. D. C. De Zoysa, K. A. D. C. Dilshan, and S. R. Munasinghe, “Modelling, simulation and implementation of a quadrotor UAV,” 2013 IEEE 8th Int. Conf. Ind. Inf. Syst. ICIIS 2013 - Conf. Proc., pp. 207–212, 2013.

[17] M. Reinoso, L. I. Minchala, J. P. Ortiz, D. Astudillo, and D. Verdugo, “Trajectory Tracking of a Quadrotor Using Sliding Mode Control,” vol. 14, no. 5, pp. 2157–2166, 2016.

[18] R. A. García, F. R. Rubio, and M. G. Ortega, “Robust PID Control of the Quadrotor Helicopter,” IFAC Proc., vol. 45, no. 3, pp. 229–234, 2012.

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