Subject-dependent emotion classification using a cubic support vector machine achieved an average accuracy of 95.73%, while subject-independent analysis achieved up to 83.7% accuracy.
Machine learning classifiers using statistical features from EEG signals can effectively recognize human emotions with high accuracy.
Abstract Brain signals for the human-computer interface is a research interest in recent years. The brain is the most vital part of our body. It handles and manages all types of activities of the body. Brain signals appear when neurons inside the brain send electrical impulses to communicate and elicit electrical potentials. This electrical activity can be measured by Electroencephalogram (EEG) through electrodes. EEG signals can help to recognize human emotions effectively. It is a non-invasive method to collect brain signals. In this paper, we have studied the subject-dependent and subject-independent analysis for four emotions (happy, sad, fear, and neutral) using the SEED-IV dataset of EEG signals for emotion. The raw EEG signals of the SEED-IV dataset have been preprocessed to remove unwanted signals and noise. 32 statistical features have been extracted from the preprocessed EEG signals and used as input for classifiers. Here, we achieved an average of 95.73% accuracy for 15 subjects for subject-dependent analysis for emotional classification using a cubic support vector machine (SVM). Based on cubic SVM and fine Gaussian SVM, we achieved an average classification accuracy of 78.46% and 83.7% for subject-independent analysis.
Dewangan et al. (Fri,) conducted a other in Emotion recognition (n=15). Support vector machine (SVM) classifiers for EEG signals was evaluated on Emotion classification accuracy. Subject-dependent emotion classification using a cubic support vector machine achieved an average accuracy of 95.73%, while subject-independent analysis achieved up to 83.7% accuracy.
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