Title :
Hysteresis parameter identification with limited experimental data
Author :
Iyer, Ram V. ; Shirley, Matthew E.
Author_Institution :
Dept. of Math. & Stat., Texas Tech Univ., Lubbock, TX, USA
Abstract :
The Preisach operator and its variants have been successfully used in the modeling of hysteresis observed in ferromagnetic, magnetostrictive, and piezoelectric materials. However, in designing with these "smart" materials, one has to determine a density function for the Preisach operator by using the input-output behavior of the material at hand. In this paper, we describe a method for numerically determining an approximation of the density function when there is not enough experimental data to uniquely solve for the actual density function by Mayergoyz\´s method. We present theoretical justification for our method by establishing links to regularization methods for ill-posed problems. We also present numerical results where we estimate an approximate density function from data published in the literature for a magnetostrictive actuator and two electroactive polymers.
Keywords :
actuators; dielectric hysteresis; ferromagnetic materials; flux pinning; intelligent materials; magnetic hysteresis; magnetostriction; magnetostrictive devices; piezoelectric materials; singular value decomposition; Mayergoyz method; Preisach operator; SMA actuators; SVD regularization; constrained least squares; density function; electroactive polymers; ferromagnetic material; hysteresis modeling; hysteresis parameter identification; ill-posed problems; input-output behavior; magnetostrictive actuator; magnetostrictive material; numerically approximation; piezoelectric material; singular value decomposition; smart materials; Density functional theory; Hysteresis; Least squares approximation; Least squares methods; Magnetic materials; Magnetostriction; Mathematics; Parameter estimation; Piezoelectric materials; Polymers; Constrained least squares; Preisach operator; SMA actuators; SVD regularization; density function identification; electroactive polymers; hysteresis; ill-posed problems; magnetostrictive; piezolelectric; smart materials;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2004.833427
