Title :
Estimating evoked dipole responses in unknown spatially correlated noise with EEG/MEG arrays
Author :
Dogandzic, A. ; Nehorai, Arye
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Illinois Univ., Chicago, IL, USA
fDate :
1/1/2000 12:00:00 AM
Abstract :
We present maximum likelihood (ML) methods for estimating evoked dipole responses using electroencephalography (EEG) and magnetoencephalography (MEG) arrays, which allow for spatially correlated noise between sensors with unknown covariance. The electric source is modeled as a collection of current dipoles at fixed locations and the head as a spherical conductor. We permit the dipoles´ moments to vary with time by modeling them as linear combinations of parametric or nonparametric basis functions. We estimate the dipoles´ locations and moments and derive the Cramer-Rao bound for the unknown parameters. We also propose an ML based method for scanning the brain response data, which can be used to initialize the multidimensional search required to obtain the true dipole location estimates. Numerical simulations demonstrate the performance of the proposed methods
Keywords :
antenna arrays; array signal processing; electroencephalography; magnetoencephalography; maximum likelihood estimation; medical signal processing; Cramer-Rao bound; EEG arrays; MEG arrays; ML based method; brain response data; dipoles locations; electric source; electroencephalography; evoked dipole responses; magnetoencephalography; maximum likelihood methods; multidimensional search; nonparametric basis functions; parametric basis functions; scanning; spatially correlated noise; spherical conductor; unknown parameters; unknown spatially correlated noise; Brain modeling; Conductors; Electroencephalography; Magnetic heads; Magnetic sensors; Magnetoencephalography; Maximum likelihood estimation; Multidimensional systems; Numerical simulation; Sensor arrays;
Journal_Title :
Signal Processing, IEEE Transactions on
