2012
DOI: 10.24846/v21i1y201208
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Feedback Linearization and Model Reference Adaptive Control of a Magnetic Levitation System

Abstract: Abstract:The aim of this paper is to combine two techniques to control a nonlinear Magnetic Levitation System (MLS). Firstly, a feedback linearization technique (here, exact linearization with state feedback) is applied to obtain a linear system. Secondly, the linearization is made via direct cancellation of nonlinear functions, which represent the phenomenological model of the system. Finally, to deal with the presence of uncertainty in the system model, an adaptive controller is used. The controller is based… Show more

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Cited by 11 publications
(5 citation statements)
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“…The dynamic of the system is derived based on the first principles of basic electrical and mechanical laws. The nonlinear reduced order of the magnetic levitation system described in Figure 2 is selected for the investigation [29]. This reduced order model is defined as:…”
Section: The Nonlinear Model Of the Magnetic Levitation Systemmentioning
confidence: 99%
See 1 more Smart Citation
“…The dynamic of the system is derived based on the first principles of basic electrical and mechanical laws. The nonlinear reduced order of the magnetic levitation system described in Figure 2 is selected for the investigation [29]. This reduced order model is defined as:…”
Section: The Nonlinear Model Of the Magnetic Levitation Systemmentioning
confidence: 99%
“…To make the system stable, all the poles must be with real negative parts. The control 𝒗 is obtained as (29).…”
Section: Design Of a Linear Control For The Linearized Closed-loop Sy...mentioning
confidence: 99%
“…Recently, a variety of control strategies have been presented and discussed for the levitation system. For instance, the feedback linearization [3] or feedforward linearization [4] technology was applied to design a trajectory tracking controller for a nonlinear maglev system. Fuzzy-PID control [5] and adaptive control [3,6,7], sliding-model control [8], fuzzy control [9,10], neural network control [11] and predictive control [1,[12][13][14] were also used to achieve the trajectory tracking in order to improve the robustness and to expand the range of effective control.…”
Section: Introductionmentioning
confidence: 99%
“…Although it outperforms the classical tuned PID controller, the performance may significantly degrade with an increasing deviation from nominal operating points. In [5]- [7], a nonlinear controller is designed by using feedback linearization. Robust control [8], [9] and low-bias control [10] are also utilized for the regulation problem.…”
Section: Introductionmentioning
confidence: 99%