The Cost of Simplicity: How Reducing EEG Electrodes Affects Source Localization and BCI Accuracy

Abstract: Electrode density optimization in electroencephalography (EEG)-based Brain-Computer Interfaces (BCIs) requires balancing practical usability against signal fidelity, particularly for source localization. Reducing electrodes enhances portability but its effects on neural source reconstruction quality and source connectivity - treated as proxies to BCI performance - remain understudied. We address this gap through systematic evaluation of 62-, 32-, and 16-channel configurations using a fixed, fully automated processing pipeline applied to the well-characterized P300 potential. This approach's rationale is to minimize variability and bias inherent to EEG analysis by leveraging the P300's stimulus-locked reproducibility and pipeline standardization. Analyzing 63 sessions (31 subjects) from the Eye-BCI dataset with rigorous artifact correction and channel validation, we demonstrate: (1) Progressive degradation in source reconstruction quality with sparser configurations, including obscured deep neural generators and spatiotemporal distortions; (2) A novel sqrt(Re) scaling law linking electrode reduction ratio (Re) to localization accuracy - a previously unquantified relationship to the best of our knowledge; (3) While reduced configurations preserve basic P300 topography and may suffice for communicative BCIs, higher-density channels are essential for reliable deep source reconstruction. Overall, this study establishes a first step towards quantitative benchmarks for electrode selection, with critical implications for clinical BCIs requiring anatomical precision in applications like neurodegenerative disease monitoring, where compromised spatial resolution could mask pathological signatures. Most importantly, the sqrt(Re) scaling law may provide the first principled method to determine the minimal electrode density required based on acceptable error margins or expected effect sizes.