Title :
Inverse problem approach to characterize and model magnetization changes in a thin shell structure undergoing magneto-mechanical effects
Author :
Viana, A. ; Rouve, L.-L. ; Chadebec, O. ; Cauffet, G. ; Coulomb, J.l.
Author_Institution :
Grenoble Electr. Eng. Lab., Univ. de Grenoble, St. Martin d´´Hères, France
Abstract :
Measurement of magnetization M inside a complex ferromagnetic geometry cannot be achieved by usage of any measurement device. In this paper, we propose to use an inverse problem algorithm to determine the law of variation of M for such structures, accounting for the magneto-mechanical effects it is undergoing. The analytical law obtained leads to an intrinsic characterization model of magnetization inside the structure. Validation of the results is achieved on a prototype undergoing high mechanical stresses in low magnetic field, by comparison of the predicted magnetic signature in the vicinity of the prototype, and measurements performed by external magnetic sensors.
Keywords :
ferromagnetism; inverse problems; magnetic sensors; magnetisation; magnetomechanical effects; shells (structures); external magnetic sensors; ferromagnetic geometry; inverse problem approach; magnetic signature; magnetization changes; magnetomechanical effects; mechanical stresses; thin shell structure; Geometry; Inverse problems; Magnetic analysis; Magnetic field measurement; Magnetic sensors; Magnetization; Mechanical variables measurement; Prototypes; Stress; Structural shells;
Conference_Titel :
Electromagnetic Field Computation (CEFC), 2010 14th Biennial IEEE Conference on
Conference_Location :
Chicago, IL
Print_ISBN :
978-1-4244-7059-4
DOI :
10.1109/CEFC.2010.5481617
