Title :
Identification of magnetic aftereffect model parameters: comparison of experiment and simulations
Author :
Korman, C.E. ; Rugkwamsook, P.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., George Washington Univ., Washington, DC, USA
fDate :
9/1/1997 12:00:00 AM
Abstract :
Previously, several aftereffect models were proposed in which Preisach type hysteresis transducers are driven by stochastic inputs. Such inputs model random thermal perturbations which are the source of aftereffect phenomena. In this article, we compare experimental and numerical simulation results for the first time in order to verify the proposed models, and present an identification procedure to determine aftereffect model parameters. Numerical simulations of the aftereffect model show the well known log t-type decay in magnetization whose rate reaches a maximum near the coercive field. Comparison of these with experimental results from γ-Fe2O3 recording media show excellent agreement. Based on this comparison, we propose a practical procedure to identify the stochastic parameters of the aftereffect model
Keywords :
coercive force; ferrites; magnetic aftereffect; magnetic hysteresis; magnetic recording noise; numerical analysis; parameter estimation; stochastic processes; γ-Fe2O3 recording media; Fe2O3; Preisach type hysteresis transducers; coercive field; log t-type decay; magnetic aftereffect model parameter identification; magnetization decay; noise characteristics; numerical simulation; random thermal perturbations; stochastic inputs; stochastic parameters; Continuous time systems; Magnetic field measurement; Magnetic fields; Magnetic hysteresis; Magnetization; Stochastic resonance; Temperature; Time measurement; Transducers; Viscosity;
Journal_Title :
Magnetics, IEEE Transactions on
