Applied Sciences (Apr 2021)

Fractional-Order LQR and State Observer for a Fractional-Order Vibratory System

  • Akihiro Takeshita,
  • Tomohiro Yamashita,
  • Natsuki Kawaguchi,
  • Masaharu Kuroda

DOI
https://doi.org/10.3390/app11073252
Journal volume & issue
Vol. 11, no. 7
p. 3252

Abstract

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The present study uses linear quadratic regulator (LQR) theory to control a vibratory system modeled by a fractional-order differential equation. First, as an example of such a vibratory system, a viscoelastically damped structure is selected. Second, a fractional-order LQR is designed for a system in which fractional-order differential terms are contained in the equation of motion. An iteration-based method for solving the algebraic Riccati equation is proposed in order to obtain the feedback gains for the fractional-order LQR. Third, a fractional-order state observer is constructed in order to estimate the states originating from the fractional-order derivative term. Fourth, numerical simulations are presented using a numerical calculation method corresponding to a fractional-order state equation. Finally, the numerical simulation results demonstrate that the fractional-order LQR control can suppress vibrations occurring in the vibratory system with viscoelastic damping.

Keywords