Rotary Inverted Pendulum (RIP) is a physical system that is often used as a theoretical platform and application of non-linear, unstable, and underactuated control systems so that it poses a challenge to design controls and realize them. The mechanical construction of the system consists of a pendulum arm that rotates horizontally on the RIP base shaft and a vertical pendulum arm that swings from a downward position to an upright equilibrium position. This paper presents a model and control scheme for RIP in a modular manner, in which three controller sections are constructed and realized using Multibody Matlab. The three controller parts include: a swing-up using a positive feedback Proportional Derivative controller, a switching mode controller that works to change swing up control scheme into stabilization control when the vertical pendulum arm reaches a position around its upright equilibrium, and stabilization controller to maintain vertical arm balanced using a Proportional Derivative controller. The trajectory of the motion of the pendulum arm and the 3D visualization of the pendulum system presented using Multibody Matlab show the effectiveness of the applied method.

rotary inverted pendulum; swing-up control; proportional derivative; stabilisation control

S. Pramanik and S. Anwar, “Robust controller design for rotary inverted pendulum using H (unlimited) and Myu-synthesis techniques,” J. Eng. 2022, pp. 249–260, 2022.

A. L. M, A. Kunjumuhammed, J. Tomy, U. G, M. Sivadas and A. Mohan, “Stabilization of Rotary Inverted Pendulum using PID Controller,” 2021 8th International Conference on Smart Computing and Communications (ICSCC), pp. 376-380, 2021.

K. N. Deepak, K. Rahul Sharma, and T. Ananthan, “Model Predictive Control for rotary inverted pendulum using LabVIEW,” IOP Conf. Ser.: Mater. Sci. Eng. 577 012113.

I. Fantoni, R. Lozano, “Stabilization of the Furuta Pendulum around its homoclinic orbit,” IFAC Nonlinear control Systems, pp. 807-812, 2001.

E. Susanto, B. Rahmat and M. Ishitobi, “Stabilization of Rotary Inverted Pendulum using Proportional Derivative and Fuzzy Controls,” in the 9th International Conference on Information Technology, Computer, and Electrical Engineering (ICITACEE),2 5-26 August 2022.

J. Huang, T. Zhang, Y. Fan and J. -Q. Sun, “Control of Rotary Inverted Pendulum Using Model-Free Backstepping Technique,” IEEE Access, vol. 7, pp. 96965-96973, 2019.

Y.F. Chen and A.C. Huang, “Adaptive control of rotary inverted pendulum system with time-varying uncertainties,” Nonlinear Dyn., vol. 76, no. 1, pp. 95–102, 2014.

I. Yiit, “Model free sliding mode stabilizing control of a real rotary inverted pendulum,” J. Vib. Control, vol. 23, no. 10, pp. 1645–1662, 2017.

K.J. Åström and K. Furuta, “Swinging up a pendulum by energy control,” Automatica, vol. 36 no. 2, pp. 287–295, 2000.

Z. Wang, Y. Chen, and N. Fang, “Minimum-time swing-up of a rotary inverted pendulum by iterative impulsive control,” Proceedings of the American control conference (ACC), pp. 1335–1340, 2004.

N.P. Nguyen, H. Oh, Y. Kim and J. Moon, “A nonlinear hybrid controller for swinging-up and stabilizing the rotary inverted pendulum,” Nonlinear Dyn, vol. 104, pp. 1117–1137, 2021.

X. Diao., “Modular Control of a Rotary Inverted Pendulum System,” 123rd ASEE Annual Conference and Exposition, New Orleans, June 26-29, 2016.

E. Susanto, “Desain dan Analisa Sistem Kendali,” Penerbit Salemba Teknika ISBN 978-979-9549-55-6, 2021.