ORCID
- Howard, Ian: 0000-0002-6041-9669
Abstract
We present an inverted pendulum design using readily available V-slot rail components and 3D printing to construct custom parts. To enable the examination of different pendulum characteristics, we constructed three pendulum poles of different lengths. We implemented a brake mechanism to modify sliding friction resistance and built a paddle that can be attached to the ends of the pendulum poles. A testing rig was also developed to consistently apply disturbances by tapping the pendulum pole, characterizing balancing performance. We perform a comprehensive analysis of the behavior and control of the pendulum. This begins by considering its dynamics, including the nonlinear differential equation that describes the system, its linearization, and its representation in the s-domain. The primary focus of this work is the development of two distinct control modes for the pendulum: a velocity control mode, designed to balance the pendulum while the cart is in motion, and a position control mode, aimed at maintaining the pendulum cart at a specific location. For this, we derived two different state space models: one for implementing the velocity control mode and another for the position control mode. In the position control mode, integral action applied to the cart position ensures that the inverted pendulum remains balanced and maintains its desired position on the rail. For both models, linear observer-based state feedback controllers were implemented. The control laws are designed as linear quadratic regulators (LQR), and the systems are simulated in MATLAB. To actuate the physical pendulum system, a stepper motor was used, and its controller was assembled in a DIN rail panel to simplify the integration of all necessary components. We examined how the optimized performance, achieved with the medium-length pendulum pole, translates to poles of other lengths. Our findings reveal distinct behavioral differences between the control modes.
DOI
10.25046/aj080613
Publication Date
2023-12-30
Publication Title
Advances in Science, Technology and Engineering Systems Journal
Volume
8
Issue
6
ISSN
2415-6698
Organisational Unit
School of Engineering, Computing and Mathematics
Keywords
3D printing, Inverted pendulum, State space control, LQR, Luenberger observer
Recommended Citation
Alvarez Hidalgo, L., & Howard, I. (2023) 'Dual Mode Control of an Inverted Pendulum: Design, Analysis and Experimental Evaluation', Advances in Science, Technology and Engineering Systems Journal, 8(6). Available at: https://doi.org/10.25046/aj080613