Abstract
Abstract. Electroencephalography (EEG) source imaging aims to reconstruct brain
activity maps from the neuroelectric potential difference measured on the skull. To
obtain the brain activity map, we need to solve an ill-posed and ill-conditioned
inverse problem that requires regularization techniques to make the solution viable.
When dealing with real-time applications, dimensionality reduction techniques can be
used to reduce the computational load required to evaluate the numerical solution
of the EEG inverse problem. To this end, in this paper we use the random dipole
sampling method, in which a Monte Carlo technique is used to reduce the number
of neural sources. This is equivalent to reducing the number of the unknowns
in the inverse problem and can be seen as a first regularization step. Then, we
solve the reduced EEG inverse problem with two popular inversion methods, the
weighted Minimum Norm Estimate (wMNE) and the standardized LOw Resolution
brain Electromagnetic TomogrAphy (sLORETA). The main result of this paper is the
error estimates of the reconstructed activity map obtained with the randomized version
of wMNE and sLORETA. Numerical experiments on synthetic EEG data demonstrate
the effectiveness of the random dipole sampling method.
Anno
2023
Autori IAC
Tipo pubblicazione
Altri Autori
L. Della Cioppa, M. Tartaglione, A. Pascarella and F. Pitolli
Editore
IOP Publishing.
Rivista
Inverse problems (Online)