Estimating Learning Effects: A Short-Time Fourier Transform Regression Model for MEG Source Localization
Abstract
Magnetoencephalography (MEG) has a high temporal resolution well-suited for studying perceptual learning. However, to identify where learning happens in the brain, one needs to ap- ply source localization techniques to project MEG sensor data into brain space. Previous source localization methods, such as the short-time Fourier transform (STFT) method by Gramfort et al.([Gramfort et al., 2013]) produced intriguing results, but they were not designed to incor- porate trial-by-trial learning effects. Here we modify the approach in [Gramfort et al., 2013] to produce an STFT-based source localization method (STFT-R) that includes an additional regression of the STFT components on covariates such as the behavioral learning curve. We also exploit a hierarchical L 21 penalty to induce structured sparsity of STFT components and to emphasize signals from regions of interest (ROIs) that are selected according to prior knowl- edge. In reconstructing the ROI source signals from simulated data, STFT-R achieved smaller errors than a two-step method using the popular minimum-norm estimate (MNE), and in a real-world human learning experiment, STFT-R yielded more interpretable results about what time-frequency components of the ROI signals were correlated with learning.
Cite
@article{arxiv.1512.00899,
title = {Estimating Learning Effects: A Short-Time Fourier Transform Regression Model for MEG Source Localization},
author = {Ying Yang and Michael J. Tarr and Robert E. Kass},
journal= {arXiv preprint arXiv:1512.00899},
year = {2015}
}
Comments
Author manuscript accepted to 4th NIPS Workshop on Machine Learning and Interpretation in Neuroimaging (2014), (in press on Lecture Notes in Computer Science, by Springer)