Learning from Heterogeneous EEG Signals with Differentiable Channel
Reordering
- URL: http://arxiv.org/abs/2010.13694v1
- Date: Wed, 21 Oct 2020 12:32:34 GMT
- Title: Learning from Heterogeneous EEG Signals with Differentiable Channel
Reordering
- Authors: Aaqib Saeed, David Grangier, Olivier Pietquin, Neil Zeghidour
- Abstract summary: CHARM is a method for training a single neural network across inconsistent input channels.
We perform experiments on four EEG classification datasets and demonstrate the efficacy of CHARM.
- Score: 51.633889765162685
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We propose CHARM, a method for training a single neural network across
inconsistent input channels. Our work is motivated by Electroencephalography
(EEG), where data collection protocols from different headsets result in
varying channel ordering and number, which limits the feasibility of
transferring trained systems across datasets. Our approach builds upon
attention mechanisms to estimate a latent reordering matrix from each input
signal and map input channels to a canonical order. CHARM is differentiable and
can be composed further with architectures expecting a consistent channel
ordering to build end-to-end trainable classifiers. We perform experiments on
four EEG classification datasets and demonstrate the efficacy of CHARM via
simulated shuffling and masking of input channels. Moreover, our method
improves the transfer of pre-trained representations between datasets collected
with different protocols.
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