Deconvolution of High-Resolution Magnetic Field Scans for Improved Current Density Imaging

Author

Holzl, Patrick Alexander ; Zagar, Bernhard G.

Author_Institution

Inst. for Meas. Technol., Johannes Kepler Univ., Linz, Austria

Volume

50

Issue

2

fYear

2014

fDate

Feb. 2014

Firstpage

101

Lastpage

104

Abstract

Inverse problems are gaining more and more importance in the field of nondestructive testing (NDT). Magnetic imaging is an NDT method, which leads to an inverse problem if the underlying current density should be determined. With the current density, characteristics of an electrical conductor such as the geometry or the conductivity can be determined. In particular, for analyzing novel electrically conductive materials, the uniformity of the conductivity is a critical characteristic. A deconvolution-based method is presented to determine the current density distribution within an inhomogeneous electrical conductor from the resulting magnetic field measured with a state-of-the-art giant magnetoresistive magnetometer.

Keywords

current density; electrical conductivity; giant magnetoresistance; inverse problems; magnetometers; nondestructive testing; NDT method; critical characteristics; current density distribution; current density imaging; deconvolution-based method; electrical conductive materials; electrical conductivity; high-resolution magnetic field scans; inhomogeneous electrical conductor; inverse problem; magnetic imaging; nondestructive testing; state-of-the-art giant magnetoresistive magnetometer; Conductivity; Current density; Deconvolution; Magnetic resonance imaging; Magnetometers; Nonhomogeneous media; Conductivity measurement; deconvolution; inverse problems; magnetometer;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2013.2284502

Filename

6749228