Experimental Implementation of a Hybrid Nonlinear Control Design for Magnetostrictive Actuators

Abstract

A hybrid nonlinear optimal control design is experimentally implemented on a ferromagnetic Terfenol-D actuator to illustrate enhanced tracking control at relatively high speed. The control design employs a homogenized energy model to quantify rate-dependent nonlinear and hysteretic ferromagnetic switching behavior. The homogenized energy model is incorporated into a finite-dimensional nonlinear optimal control design to directly compensate for the nonlinear and hysteretic ferromagnetic constitutive behavior of the Terfenol-D actuator. Additionally, robustness to operating uncertainties is addressed by incorporating proportional-integral (PI) perturbation feedback around the optimal open loop response. Experimental results illustrate significant improvements in tracking control in comparison to PI control. Accurate displacement tracking is achieved for sinusoidal reference displacements at frequencies up to 1 kHz using the hybrid nonlinear control design whereas tracking errors become significant for the PI controller for frequencies equal to or greater than 500 Hz.

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Document Details

Document Type
Technical Report
Publication Date
Jan 01, 2006
Accession Number
ADA459020

Entities

People

  • Marcelo J. Dapino
  • Phillip G. Evans
  • Ralph C. Smith
  • William S Oates

Organizations

  • Florida State University

Tags

Communities of Interest

  • Advanced Electronics
  • Biomedical
  • Space

DTIC Thesaurus Topics

  • Actuators
  • Amplifiers
  • Differential Equations
  • Eddy Currents
  • Electrical Impedance
  • Equations
  • Feedback
  • Frequency
  • Frequency Response
  • Integrals
  • Magnetic Fields
  • Materials
  • Numerical Analysis
  • Partial Differential Equations
  • Perturbations
  • Power Amplifiers
  • Switching

Fields of Study

  • Physics

Readers

  • Adaptive Control and Estimation with Uncertainty in Dynamic Systems.
  • Materials Science and Engineering.