Akademik Veri Yönetim Sistemi
International Journal of Neural Systems, 2026 (SCI-Expanded, Scopus)
Brain–computer interface (BCI) technology supports the interactions of individuals with severe neuromuscular limitations with their environment. This work presents a classification approach for distinguishing motor imagery (MI) from speech-related cognitive imagery (CI) such as word generation and arithmetic subtraction, using magnetoencephalography (MEG) signals. Differentiating MI and CI/SI processes is relevant for expanding command diversity in hybrid BCI systems and for clarifying the distinct neural mechanisms underlying motor versus verbal–semantic processing. Although a large proportion of noninvasive BCI studies focus on MI, this distinction has received relatively limited attention, particularly in MEG-based approaches. Making this distinction is important for increasing command diversity in hybrid BCI systems and for improving the understanding of neural mechanisms associated with motor and verbal–semantic processing. Tasks from an open-access MEG dataset were analyzed across six binary pairs (H–F, H–W, H–S, F–W, F–S, W–S). MEG signals were processed using two frequency-separation strategies: a broad-band configuration (FSB-1: 8–14 Hz and 14–30 Hz) and a narrow-band configuration (FSB-2: six sub-bands between 8 and 32 Hz). Time–frequency features were extracted using continuous wavelet transform (CWT), and spatial features via the common spatial pattern (CSP) method. Feature selection followed a two-stage procedure: (i) t-test ranking to obtain a shared feature set for all task pairs; and (ii) subject- and task-specific optimization of feature number. The initial evaluation based on the shared feature set showed that the FSB-2/CWT approach yielded better classification accuracies compared to FSB-1/CWT (H-F: 56%, H-W: 71%, H-S: 66% versus 54%, 68%, 64%). With subject- and task-adaptive optimization, additional improvements were observed. Accuracies increased to 60%, 72%, and 69% for FSB-1, and to 63%, 75%, and 71% for FSB-2, for H–F, H–W, and H–S, respectively. Overall, the findings indicate that the proposed CWT+CSP framework, particularly when combined with adaptive feature optimization, offers an interpretable analysis approach that can contribute to MI–CI discrimination in MEG-based BCI systems under limited data conditions.