Title :
Optimizing Spatial filters for Robust EEG Single-Trial Analysis
Author :
Blankertz, Benjamin ; Tomioka, Ryota ; Lemm, S. ; Kawanabe, M. ; Muller, Klaus-Robert
Author_Institution :
Tech. Univ. Berlin, Berlin
fDate :
6/30/1905 12:00:00 AM
Abstract :
Due to the volume conduction multichannel electroencephalogram (EEG) recordings give a rather blurred image of brain activity. Therefore spatial filters are extremely useful in single-trial analysis in order to improve the signal-to-noise ratio. There are powerful methods from machine learning and signal processing that permit the optimization of spatio-temporal filters for each subject in a data dependent fashion beyond the fixed filters based on the sensor geometry, e.g., Laplacians. Here we elucidate the theoretical background of the common spatial pattern (CSP) algorithm, a popular method in brain-computer interface (BCD research. Apart from reviewing several variants of the basic algorithm, we reveal tricks of the trade for achieving a powerful CSP performance, briefly elaborate on theoretical aspects of CSP, and demonstrate the application of CSP-type preprocessing in our studies of the Berlin BCI (BBCI) project.
Keywords :
electroencephalography; learning (artificial intelligence); medical signal processing; neurophysiology; spatial filters; user interfaces; Berlin BCI project; brain activity; brain-computer interface; common spatial pattern algorithm; electroencephalogram; machine learning; robust EEG analysis; signal processing; signal-to-noise ratio; single-trial analysis; spatial filters; spatiotemporal filters; volume conduction multichannel EEG; Brain; Electroencephalography; Geometry; Machine learning; Optimization methods; Robustness; Signal analysis; Signal processing algorithms; Signal to noise ratio; Spatial filters;
Journal_Title :
Signal Processing Magazine, IEEE
DOI :
10.1109/MSP.2008.4408441
