Complex fractional-order LQIR for inverted-pendulum-type robotic mechanisms : design and experimental validation
Saleem, Omer and Abbas, Faisal and Iqbal, Jamshed (2023) Complex fractional-order LQIR for inverted-pendulum-type robotic mechanisms : design and experimental validation. Mathematics, 11 (4). 913. ISSN 2227-7390 (https://doi.org/10.3390/math11040913)
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Abstract
This article presents a systematic approach to formulate and experimentally validate a novel Complex Fractional Order (CFO) Linear Quadratic Integral Regulator (LQIR) design to enhance the robustness of inverted-pendulum-type robotic mechanisms against bounded exogenous disturbances. The CFO controllers, an enhanced variant of the conventional fractional-order controllers, are realised by assigning pre-calibrated complex numbers to the order of the integral and differential operators in the control law. This arrangement significantly improves the structural flexibility of the control law, and hence, subsequently strengthens its robustness against the parametric uncertainties and nonlinear disturbances encountered by the aforementioned under-actuated system. The proposed control procedure uses the ubiquitous LQIR as the baseline controller that is augmented with CFO differential and integral operators. The fractional complex orders in LQIR are calibrated offline by minimising an objective function that aims at attenuating the position-regulation error while economising the control activity. The effectiveness of the CFO-LQIR is benchmarked against its integer and fractional-order counterparts. The ability of each controller to mitigate the disturbances in inverted-pendulum-type robotic systems is rigorously tested by conducting real-time experiments on Quanser single-link rotary pendulum system. The experimental outcomes validate the superior disturbance rejection capability of the CFO-LQIR by yielding rapid transits and strong damping against disturbances while preserving the control input economy and closed-loop stability of the system.
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Item type: Article ID code: 84432 Dates: DateEvent10 February 2023Published7 February 2023AcceptedSubjects: Science > Mathematics
Technology > Engineering (General). Civil engineering (General) > Engineering designDepartment: Faculty of Science > Strathclyde Institute of Pharmacy and Biomedical Sciences Depositing user: Pure Administrator Date deposited: 27 Feb 2023 15:14 Last modified: 29 Nov 2024 04:32 URI: https://strathprints.strath.ac.uk/id/eprint/84432