Nonlinear Control of a Magnetic Levitation System Using a New Input-Output Feedback Linearization

Abstract In this paper a nonlinear controller (NLC) is designed for a Magnetic Levitation System (MLS). The proposed NLC uses a new input-output based differential geometry feedback linearization method in conjugation with a linear state feedback controller in outer loop to levitate a ferromagnetic ball. The electromagnetic force, which is a function of input magnetizing current and position of the ferromagnetic material to be levitated by the applied input force, is estimated using real-time experimental data. The simulation results obtained show efficacy of the proposed NLC in comparison to a traditional PID controller.

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