Title :
Optimizing spatial filters for the extraction of envelope-coupled neural oscillations
Author :
Dahne, Sven ; Nikulin, Vladimir ; Ramirez, Diego ; Schreier, Peter J. ; Muller, Klaus-Robert ; Haufer, Stefan
Author_Institution :
Dept. of Machine Learning, Berlin Inst. of Technol., Berlin, Germany
Abstract :
Amplitude-to-amplitude interactions between neural oscillations are of a special interest as they show how the strength of spatial synchronization in different neuronal populations relates to each other during a given task. While, previously, amplitude-to-amplitude correlations were studied primarily on the sensor level, we present a source separation approach using spatial filters which maximize the correlation between the envelopes of brain oscillations recorded with electro-/magnetencephalography (EEG/MEG) or intracranial multichannel recordings. Our approach, which is called canonical source power correlation analysis (cSPoC), is thereby capable of extracting genuine brain oscillations solely based on their assumed coupling behavior even when the signal-to-noise ratio of the signals is low.
Keywords :
electroencephalography; feature extraction; magnetoencephalography; medical signal processing; neurophysiology; oscillations; signal denoising; source separation; spatial filters; EEG-MEG; amplitude-to-amplitude interactions; canonical source power correlation analysis; electroencephalography-magnetencephalography; envelope-coupled neural oscillation extraction; genuine brain oscillations; intracranial multichannel recordings; neuronal populations; sensor level; signal-to-noise ratio; source separation approach; spatial filter optimization; spatial synchronization strength; Brain modeling; Correlation; Couplings; Data models; Electroencephalography; Oscillators; Signal to noise ratio;
Conference_Titel :
Pattern Recognition in Neuroimaging, 2014 International Workshop on
Conference_Location :
Tubingen
Print_ISBN :
978-1-4799-4150-6
DOI :
10.1109/PRNI.2014.6858514
