Statistical performance analysis of signal variance-based dipole models for MEG/EEG source localization and detection

A set of dipole fitting algorithms that incorporate different assumptions about the variability of the signal component into their mathematical models is presented and analyzed. Dipole fitting is performed by minimizing the squared error between the selected data model and available data. Dipole mod...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering 2003-02, Vol.50 (2), p.137-149
Main Authors: Rodriguez-Rivera, A., Van Veen, B.D., Wakai, R.T.
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Algorithm design and analysis
Algorithms
Biological and medical sciences
Brain Mapping - methods
Brain modeling
Computer Simulation
Delay
Electroencephalography
Electroencephalography - methods
Electromagnetic Fields
Epilepsy
Epilepsy - physiopathology
False Positive Reactions
Humans
Magnetoencephalography - methods
Mathematical model
Mathematical models
Medical sciences
Models, Neurological
Models, Statistical
Morphology
Neurons - physiology
Performance analysis
Quality Control
Reproducibility of Results
Sensitivity and Specificity
Signal analysis
Signal detection
Stochastic Processes
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Description
Summary:A set of dipole fitting algorithms that incorporate different assumptions about the variability of the signal component into their mathematical models is presented and analyzed. Dipole fitting is performed by minimizing the squared error between the selected data model and available data. Dipole models based on moments that have 1) constant amplitude and orientation, 2) variable amplitude and fixed known orientation, 3) variable amplitude and fixed unknown orientation, and 4) variable amplitude and variable orientation are considered. The presence of a dipolar source is determined by comparing the fractional energy explained by the dipole model to a threshold. Source localization is accomplished by searching to find the location that explains the largest fractional signal energy using a dipole model. Expressions for the probability of a false positive decision and probability of correct detection are derived and used to evaluate the effect of variability in the dipole on performance and to address the effects of model mismatch and location errors. Simulated and measured data experiments are presented to illustrate the performance of both detection and localization methods. The results indicate that models which account for variance outperform the constant orientation and magnitude model even when the number of observations is relatively small and the signal of interest contains a very modest variance component.
ISSN:0018-9294
1558-2531
DOI:10.1109/TBME.2002.807661