Performance enhancement of steady-state visual evoked field-based brain-computer interfaces incorporating MEG source imagingopen accessPerformance Enhancement of Steady-State Visual Evoked Field-Based Brain–Computer Interfaces Incorporating MEG Source Imaging
- Other Titles
- Performance Enhancement of Steady-State Visual Evoked Field-Based Brain–Computer Interfaces Incorporating MEG Source Imaging
- Authors
- Kim, Ye-Sung; Han, Hyojeong; Kim, Cheong-Un; Choi, Soo-In; Kim, Min-Young; Im, Chang-Hwan
- Issue Date
- Jul-2025
- Publisher
- Institute of Electrical and Electronics Engineers
- Keywords
- brain-computer interface (BCI); Magnetoencephalography (MEG); source imaging; steady-state visual-evoked field (SSVEF)
- Citation
- IEEE Transactions on Neural Systems and Rehabilitation Engineering, v.33, pp 2806 - 2813
- Pages
- 8
- Indexed
- SCIE
SCOPUS
- Journal Title
- IEEE Transactions on Neural Systems and Rehabilitation Engineering
- Volume
- 33
- Start Page
- 2806
- End Page
- 2813
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/209647
- DOI
- 10.1109/TNSRE.2025.3590576
- ISSN
- 1534-4320
1558-0210
- Abstract
- Recent advancements in helmet-type magneto-encephalography (MEG) systems that operate without liquid helium, such as optically pumped magnetometer (OPM)-based MEG, have increased interest in MEG-based brain–computer interfaces (BCIs). Among various BCI paradigms, steady-state visual evoked field (SSVEF)-based BCIs have been actively studied owing to their high information transfer rate (ITR) and low demand for calibration sessions. Although MEG provides excellent spatial resolution and whole-head coverage, conventional algorithms such as the filter bank-driven multivariate synchronization index (FBMSI) do not fully exploit these advantages. To overcome this limitation, this study employed MEG source imaging to utilize information from whole-head MEG recordings fully and developed a novel weighting method called the averaged source location-based weighting (ASLW). ASLW leverages the averaged source locations of SSVEF signals to enhance BCI performance. Experimental results with 20 participants demonstrated that integrating ASLW with the FBMSI algorithm (ASLW-FBMSI) significantly improved both the classification accuracy and ITR across all tested window sizes. Notably, the largest performance gains included a 13.9% accuracy improvement at a 3-s window size and a 13.1 bits/min increase in ITR at a 2.5-s window size. Additionally, the ASLW-FBMSI algorithm exhibited a short processing delay of 0.107 s at a 4-s data length and was successfully validated in online BCI experiments with 20 participants. Although tested in SQUID-MEG in this study, our findings demonstrate the effectiveness of ASLW in significantly enhancing the overall performance of SSVEF-based BCIs.
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