Depth normalization in MEG/EEG current density imaging

Author

Köhler, Th ; Wagner, M. ; Fuchs, M. ; Wischmann, H.A. ; Drenckhahn, R. ; Theißen, A.

Author_Institution

Philips GmbH Forschungslab., Hamburg, Germany

Volume

2

fYear

1996

fDate

31 Oct-3 Nov 1996

Firstpage

812

Abstract

We analyze the minimum norm solution of the biomagnetic inverse problem. It is shown that the bias of this technique, i.e. the tendency to reconstruct superficial currents, can be reduced by the use of an appropriate weighting, which depends the used norm. The weighting factors are calculated by a singular value decomposition of the lead field matrix for each location and a noise regularization technique. With this weighting, the ability to reconstruct deep sources is maintained over the whole volume of sensitivity. The extend of this volume depends on the measurement setup and the noise level

Keywords

current density; electroencephalography; electron device noise; inverse problems; magnetoencephalography; medical image processing; singular value decomposition; MEG/EEG current density imaging; biomagnetic inverse problem; deep sources; depth normalization; lead field matrix; measurement setup; minimum norm solution; noise level; noise regularization technique; singular value decomposition; superficial currents; weighting factors; Biomagnetics; Current density; Electroencephalography; Image reconstruction; Inverse problems; Matrix decomposition; Noise level; Noise measurement; Singular value decomposition; Volume measurement;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society, 1996. Bridging Disciplines for Biomedicine. Proceedings of the 18th Annual International Conference of the IEEE

Conference_Location

Amsterdam

Print_ISBN

0-7803-3811-1

Type

conf

DOI

10.1109/IEMBS.1996.651989

Filename

651989