Zero-calibration cVEP BCI using word prediction: a proof of concept
This addresses the problem of reducing setup time and improving usability for users of c-VEP BCIs, though it appears incremental as it builds on existing c-VEP frameworks.
The paper tackles the need for calibration in code-modulated visual evoked potential (c-VEP) brain-computer interfaces (BCIs) for spelling by proposing a zero-calibration method that extracts relative lags between characters and uses word prediction with a dictionary, demonstrating a proof of concept to eliminate the initial calibration phase.
Brain Computer Interfaces (BCIs) based on visual evoked potentials (VEP) allow for spelling from a keyboard of flashing characters. Among VEP BCIs, code-modulated visual evoked potentials (c-VEPs) are designed for high-speed communication . In c-VEPs, all characters flash simultaneously. In particular, each character flashes according to a predefined 63-bit binary sequence (m-sequence), circular-shifted by a different time lag. For a given character, the m-sequence evokes a VEP in the electroencephalogram (EEG) of the subject, which can be used as a template. This template is obtained during a calibration phase at the beginning of each session. Then, the system outputs the desired character after a predefined number of repetitions by estimating its time lag with respect to the template. Our work avoids the calibration phase, by extracting from the VEP relative lags between successive characters, and predicting the full word using a dictionary.