Electromagnetic field distribution and developed losses inside a finite cylinder and sphere under MRI conditions

Author

Sergiadis, G. ; Sakellaris, J. ; Kriezis, E.E.

Author_Institution

Thessaloniki Univ., Greece

Volume

7

Issue

4

fYear

1988

Firstpage

381

Lastpage

385

Abstract

The control of the thermal losses dissipated inside the human body during magnetic resonance imaging (MRI) is very important, since it is directly related to patient safety. The authors give the exact solution to the problem of the electromagnetic energy dissipation and distribution inside a conductive sphere and a finite conductive cylinder, considered as the closest models to the human anatomy. The high-frequency alternating magnetic field is produced by a current loop. Numerical results are given for alternating fields from 6 to 100 MHz and various excitation geometries. The results, which take into account the magnetic field inhomogeneities and the finite dimensions of the conductive models, apply not only to the MRI experiments but also to any similar eddy-current problem.<>

Keywords

biomedical NMR; patient diagnosis; 6 to 100 MHz; HF alternating magnetic field; conductive sphere; current loop; eddy-current problem; electromagnetic field distribution; excitation geometry; finite conductive cylinder; magnetic field inhomogeneities; magnetic resonance imaging; patient safety; thermal losses; Biological system modeling; Biological tissues; Dielectric losses; Electromagnetic fields; Frequency; Magnetic fields; Magnetic resonance imaging; Safety; Solids; Thermal conductivity;

fLanguage

English

Journal_Title

Medical Imaging, IEEE Transactions on

Publisher

ieee

ISSN

0278-0062

Type

jour

DOI

10.1109/42.14522

Filename

14522