Optimal Feature Selection and Deep Learning Ensembles Method for Emotion Recognition From Human Brain EEG Sensors

Optimal Feature Selection and Deep Learning Ensembles Method for Emotion Recognition From Human Brain EEG Sensors

Blog Article

Recent advancements in human-computer interaction research have led to the possibility of emotional communication via brain-computer interface systems for patients with neuropsychiatric disorders or disabilities.In this paper, we efficiently recognize emotional states by analyzing the features of electroencephalography (EEG) signals, which are generated from EEG sensors that noninvasively measure the electrical activity of neurons inside the human brain, and select the optimal combination of these features for recognition.In this paper, the scalp EEG data of 21 healthy subjects (12-14 years old) were recorded using #felt saddle pad a 14-channel EEG machine while the subjects watched images with four types of emotional stimuli (happy, calm, sad, or scared).After preprocessing, the Hjorth parameters (activity, mobility, and complexity) were used to measure the signal activity of the time series data.

We selected the optimal EEG features using a balanced one-way ANOVA after calculating the Hjorth parameters for different frequency ranges.Features selected by this statistical method outperformed univariate and multivariate features.The optimal features were further processed for emotion classification using support vector machine, k-nearest neighbor, linear discriminant analysis, Naive Bayes, random forest, deep learning, and four ensembles methods (bagging, boosting, stacking, and voting).The results show that the Printer proposed method substantially improves the emotion recognition rate with respect to the commonly used spectral power band method.