A modeling study comparing the signal-to-noise ratio between tripolar concentric ring and conventional disk electrodes with added common mode noise

Authors

X. Liu, University of Rhode Island
W. Besio, University of Rhode Island

Document Type

Conference Proceeding

Date of Original Version

1-1-2009

Abstract

Electroencephalography (EEG) has high temporal resolution, but lacks high spatial resolution even after increasing the number of electrodes. Although EEG is intended to record cerebral activity, it also records electrical activities arising from sites other than the brain, artifacts. To remove major artifacts like electrooculogram (EOG), electrocardiogram (EMG) and ECG present in EEG, many techniques have been proposed among which surface Laplacian spatial filtering has found prominence. The authors have compared a Laplacian Tripolar concentric ring electrode system to Disc electrodes in terms of the signal-to-noise ratio (SNR). A four-layer anisotropic concentric spherical head computer model was programmed, then a time-varying dipole was used to generate the scalp surface signals that would be obtained with tripolar and disc electrodes. Common mode white noise was added to the electrodes. Finally, the signal-to-noise ratio was calculated. The results show that signals from tripolar electrodes generated much better signal-to-noise ratio.

Publication Title, e.g., Journal

Proceedings of the IEEE Annual Northeast Bioengineering Conference Nebec

Citation/Publisher Attribution

Liu, X., and W. Besio. "A modeling study comparing the signal-to-noise ratio between tripolar concentric ring and conventional disk electrodes with added common mode noise." Proceedings of the IEEE Annual Northeast Bioengineering Conference Nebec (2009). doi: 10.1109/NEBC.2009.4967782.