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Пишет bioRxiv Subject Collection: Neuroscience (![[info]](http://lj.rossia.org/img/syndicated.gif){kind=small} syn_bx_neuro)@ 2025-09-26 04:35:00 |
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A lightweight, physics-based, sensor-fusion filter for real-time EEGdenoising and improved downstream AI classification
Physiological time-series data, like electroencephalography (EEG), are vulnerable to motion, ocular, and muscle artifacts that hinder real-time inference and bias offline analyses. We present the Minds AI Filter: a lightweight, physics-based, sensor-fusion method that exploits multichannel spatial structure and band-aware synchrony to enhance neural activity while suppressing non- neural noise. The nomenclature "AI" reflects integration within a larger artificial-intelligence pipeline; the filter itself requires no prior training or deep learning. A single tuning parameter controls filter strength. The design supports streaming windows (approx. 1s) with minimal added latency and extends naturally to longer offline segments; leveraging a sensor-fusion design across channels, it suggests applicability to other neurophysiological time-series, such as MEG and ECoG, pending further validation; exploratory incorporation of EOG/ECG as auxiliary signals is a potential avenue for future filter advancements. We evaluate the approach across multiple devices and public datasets, assessing both down- stream AI classification performance and real-time signal-quality metrics. In both real-time and offline settings, the filter performed better on dynamic artifacts and noise than baseline and commonly used alternatives in our evaluations. When applied in conjunction with other methods, it was only observed to improve downstream accuracy, never reduce it, when any effect was present. Denoising is quantified using SNR-like measures, and ablations isolate the roles of spatial coupling and band weighting. Artifact-specific analyses (ocular bursts, head tilt, jaw clench) and latency profiling on commodity hardware are included. These results indicate that a lightweight, synchrony-aware filter can robustly stabilize real-time EEG and systematically improve downstream AI classification. The method is compatible with standard preprocessing but does not depend on it.
Physiological time-series data, like electroencephalography (EEG), are vulnerable to motion, ocular, and muscle artifacts that hinder real-time inference and bias offline analyses. We present the Minds AI Filter: a lightweight, physics-based, sensor-fusion method that exploits multichannel spatial structure and band-aware synchrony to enhance neural activity while suppressing non- neural noise. The nomenclature "AI" reflects integration within a larger artificial-intelligence pipeline; the filter itself requires no prior training or deep learning. A single tuning parameter controls filter strength. The design supports streaming windows (approx. 1s) with minimal added latency and extends naturally to longer offline segments; leveraging a sensor-fusion design across channels, it suggests applicability to other neurophysiological time-series, such as MEG and ECoG, pending further validation; exploratory incorporation of EOG/ECG as auxiliary signals is a potential avenue for future filter advancements. We evaluate the approach across multiple devices and public datasets, assessing both down- stream AI classification performance and real-time signal-quality metrics. In both real-time and offline settings, the filter performed better on dynamic artifacts and noise than baseline and commonly used alternatives in our evaluations. When applied in conjunction with other methods, it was only observed to improve downstream accuracy, never reduce it, when any effect was present. Denoising is quantified using SNR-like measures, and ablations isolate the roles of spatial coupling and band weighting. Artifact-specific analyses (ocular bursts, head tilt, jaw clench) and latency profiling on commodity hardware are included. These results indicate that a lightweight, synchrony-aware filter can robustly stabilize real-time EEG and systematically improve downstream AI classification. The method is compatible with standard preprocessing but does not depend on it.
