Using Feedforward Neural Networks to Monitor Alertness from Changes in EEG Correlation and Coherence

We report here that changes in the normalized electroencephalographic (EEG)cross-spectrum can be used in conjunction with feedforward neural networks to monitor changes in alertness of operators continuouslyand in near-real time. Previously, we have shown that EEG spectral amplitudes covary with changes in alertness asindexed by changes in behavioral error rate on an auditory detection task [6,4]. Here, we report for the first time that increases in the frequency of detection errors in this task are also accompanied bypatterns of increased and decreased spectral coherence in several frequency bands and EEG channel pairs. Relationships between EEG coherence and performance vary between subjects, but within subjects, their topographic and spectral profiles appear stable from session to session. Changes in alertness also covary with changes in correlations among EEG waveforms recorded at different scalp sites, and neural networks can also estimate alertness fromcorrelation changes in spontaneous and unobtrusivelyrecorded EEGsignals. 1 Introduction When humans become drowsy, EEG scalp recordings of potential oscillations change dramatically in frequency, amplitude, and topographic distribution [3]. These changes are complex and differ between subjects [10]. Recently, we have shown 932 S.MAKEIG, T.-P.