Transferring BCI models from calibration to control: Observing shifts in EEG features
This addresses a practical issue for BCI developers by highlighting shifts in EEG patterns during real-world control tasks, though it is incremental as it builds on existing CSP methods.
The study tackled the problem of generalization errors when transferring BCI models from calibration to control tasks by introducing a new paradigm with calibration and EMG-based control sessions, finding large differences in EEG features but demonstrating that a CSP-based model trained on calibration data can make surprisingly good predictions on control data.
Public Motor Imagery-based brain-computer interface (BCI) datasets are being used to develop increasingly good classifiers. However, they usually follow discrete paradigms where participants perform Motor Imagery at regularly timed intervals. It is often unclear what changes may happen in the EEG patterns when users attempt to perform a control task with such a BCI. This may lead to generalisation errors. We demonstrate a new paradigm containing a standard calibration session and a novel BCI control session based on EMG. This allows us to observe similarities in sensorimotor rhythms, and observe the additional preparation effects introduced by the control paradigm. In the Movement Related Cortical Potentials we found large differences between the calibration and control sessions. We demonstrate a CSP-based Machine Learning model trained on the calibration data that can make surprisingly good predictions on the BCI-controlled driving data.