Title :
Blind signal separation from optical imaging recordings with extended spatial decorrelation
Author :
Schiessl, I. ; Stetter, M. ; Mayhew, J.E.W. ; McLoughlin, N. ; Lund, J.S. ; Obermayer, K.
Author_Institution :
Dept. of Comput. Sci., Tech. Univ. Berlin, Germany
fDate :
5/1/2000 12:00:00 AM
Abstract :
Optical imaging is the video recording of two-dimensional patterns of changes in light reflectance from cortical tissue evoked by stimulation. We derived a method, extended spatial decorrelation (ESD), that uses second-order statistics in space for separating the intrinsic signals into the stimulus related components and the nonspecific variations. The performance of ESD on model data is compared to independent component analysis algorithms using statistics of fourth and higher order. Robustness against sensor noise is scored. When applied to optical images, ESD separates the stimulus specific signal well from biological noise and artifacts.
Keywords :
CCD image sensors; bio-optics; biomedical imaging; brain; decorrelation; light reflection; medical image processing; optical correlation; optical images; statistical analysis; vision; 500 to 800 nm; CCD camera; artifacts; biological noise; blind signal separation; cortical tissue; extended spatial decorrelation; intrinsic signal; light reflectance changes; nonspecific variations; optical imaging recordings; second-order statistics; sensor noise; stimulation; stimulus related components; two-dimensional patterns; video recording; visual cortex; Biological system modeling; Blind source separation; Decorrelation; Electrostatic discharge; Higher order statistics; Optical imaging; Optical noise; Optical recording; Reflectivity; Video recording; Algorithms; Animals; Brain Mapping; Computer Simulation; Electric Stimulation; Macaca mulatta; Signal Processing, Computer-Assisted; Statistics as Topic; Video Recording; Visual Cortex;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
