Evaluation of a finite-element reciprocity method for epileptic EEG source localization: Accuracy, computational complexity and noise robustness
Journal article, 2013

PURPOSE The aim of this paper is to evaluate the performance of an EEG source localization method that combines a finite element method (FEM) and the reciprocity theorem. METHODS The reciprocity method is applied to solve the forward problem in a four-layer spherical head model for a large number of test dipoles. To benchmark the proposed method, the results are compared with an analytical solution and two state-of-the-art methods from the literature. Moreover, the dipole localization error resulting from utilizing the method in the inverse procedure for a realistic head model is investigated with respect to EEG signal noise and electrode misplacement. RESULTS The results show approximately 3% relative error between numerically calculated potentials done by the reciprocity theorem and the analytical solutions. When adding EEG noise with SNR between 5 and 10, the mean localization error is approximately 4.3 mm. For the case with 10 mm electrode misplacement the localization error is 4.8 mm. The reciprocity EEG source localization speeds up the solution of the inverse problem with more than three orders of magnitude compared to the state-of-the-art methods. CONCLUSIONS The reciprocity method has high accuracy for modeling the dipole in EEG source localization, is robust with respect to noise, and faster than alternative methods.

Inverse problem

MRI

Realistic head model

Reciprocity theorem

EEG source localization

Finite element method

Author

Yazdan Shirvany

Chalmers, Signals and Systems, Signal Processing and Biomedical Engineering

Tonny Rubaek

Chalmers, Signals and Systems, Signal Processing and Biomedical Engineering

Fredrik Edelvik

Stefan Jakobsson

Oskar Talcoth

Chalmers, Signals and Systems, Signal Processing and Biomedical Engineering

Mikael Persson

Chalmers, Signals and Systems, Signal Processing and Biomedical Engineering

Biomedical Engineering Letters

2093-9868 (ISSN) 2093-985X (eISSN)

Vol. 3 1 8-16

Areas of Advance

Life Science Engineering (2010-2018)

Subject Categories

Electrical Engineering, Electronic Engineering, Information Engineering

DOI

10.1007/s13534-013-0083-1

More information

Latest update

3/2/2022 6