Using Convolutional Neural Networks to Recognize Rhythm Stimuli from Electroencephalography Recordings
Abstract
Electroencephalography (EEG) recordings of rhythm perception might contain enough information to distinguish different rhythm types/genres or even identify the rhythms themselves. We apply convolutional neural networks (CNNs) to analyze and classify EEG data recorded within a rhythm perception study in Kigali, Rwanda which comprises 12 East African and 12 Western rhythmic stimuli – each presented in a loop for 32 seconds to 13 participants. We investigate the impact of the data representation and the pre-processing steps for this classification tasks and compare different network structures. Using CNNs, we are able to recognize individual rhythms from the EEG with a mean classification accuracy of 24.4% (chance level 4.17%) over all subjects by looking at less than three seconds from a single channel. Aggregating predictions for multiple channels, a mean accuracy of up to 50% can be achieved for individual subjects.
Cite
Text
Stober et al. "Using Convolutional Neural Networks to Recognize Rhythm Stimuli from Electroencephalography Recordings." Neural Information Processing Systems, 2014.Markdown
[Stober et al. "Using Convolutional Neural Networks to Recognize Rhythm Stimuli from Electroencephalography Recordings." Neural Information Processing Systems, 2014.](https://mlanthology.org/neurips/2014/stober2014neurips-using/)BibTeX
@inproceedings{stober2014neurips-using,
title = {{Using Convolutional Neural Networks to Recognize Rhythm Stimuli from Electroencephalography Recordings}},
author = {Stober, Sebastian and Cameron, Daniel J and Grahn, Jessica A},
booktitle = {Neural Information Processing Systems},
year = {2014},
pages = {1449-1457},
url = {https://mlanthology.org/neurips/2014/stober2014neurips-using/}
}