Abstract
In this study we explore how different levels of emotional intensity (Arousal) and pleasantness (Valence) are reflected in electroencephalographic (EEG) signals. We performed the experiments on EEG data of 32 subjects from the DEAP public dataset, where the subjects were stimulated using 60-s videos to elicitate different levels of Arousal/Valence and then self-reported the rating from 1 to 9 using the self-assessment Manikin (SAM). The EEG data was pre-processed and used as input to a convolutional neural network (CNN). First, the 32 EEG channels were used to compute the maximum accuracy level obtainable for each subject as well as for creating a single model using data from all the subjects. The experiment was repeated using one channel at a time, to see if specific channels contain more information to discriminate between low vs high arousal/valence. The results indicate than using one channel the accuracy is lower compared to using all the 32 channels. An optimization process for EEG channel selection is then designed with the Non-dominated Sorting Genetic Algorithm II (NSGA-II) with the objective to obtain optimal channel combinations with high accuracy recognition. The genetic algorithm evaluates all possible combinations using a chromosome representation for all the 32 channels, and the EEG data from each chromosome in the different populations are tested iteratively solving two unconstrained objectives; to maximize classification accuracy and to reduce the number of required EEG channels for the classification process. Best combinations obtained from a Pareto-front suggests that as few as 8–10 channels can fulfill this condition and provide the basis for a lighter design of EEG systems for emotion recognition. In the best case, the results show accuracies of up to 1.00 for low vs high arousal using eight EEG channels, and 1.00 for low vs high valence using only two EEG channels. These results are encouraging for research and healthcare applications that will require automatic emotion recognition with wearable EEG.
Highlights
We explored the use of convolutional neural network (CNN) through the EEGNet architecture, testing first the use of all the EEG channels available for Low vs High Arousal and Low vs High Valence classification
We tested a previously proposed method for feature extraction based on Discrete Wavelet Transform (DWT) with four decomposition levels, and for each sub-band extracted, the Teager and instantaneous energy, Higuchi and Petrosian fractal dimension features were computed, obtaining 5 ∗ 4 = 20 features for each EEG channel[52–56]
The obtained features from all the EEG channels were used as input for Support Vector Machine (SVM), naive Bayes (NB) and k-Nearest Neighbors (kNN) classifiers using 10-fold cross validation to compute the accuracy
Summary
Since our objective is the optimal reduction of the number of channels used in the classification process, and
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