Abstract
Emotion recognition using electroencephalogram (EEG) signals has attracted significant research attention. However, it is difficult to improve the emotional recognition effect across subjects. In response to this difficulty, in this study, multiple features were extracted for the formation of high-dimensional features. Based on the high-dimensional features, an effective method for cross-subject emotion recognition was then developed, which integrated the significance test/sequential backward selection and the support vector machine (ST-SBSSVM). The effectiveness of the ST-SBSSVM was validated on a dataset for emotion analysis using physiological signals (DEAP) and the SJTU Emotion EEG Dataset (SEED). With respect to high-dimensional features, the ST-SBSSVM average improved the accuracy of cross-subject emotion recognition by 12.4% on the DEAP and 26.5% on the SEED when compared with common emotion recognition methods. The recognition accuracy obtained using ST-SBSSVM was as high as that obtained using sequential backward selection (SBS) on the DEAP dataset. However, on the SEED dataset, the recognition accuracy increased by ~6% using ST-SBSSVM from that using the SBS. Using the ST-SBSSVM, ~97% (DEAP) and 91% (SEED) of the program runtime was eliminated when compared with the SBS. Compared with recent similar works, the method developed in this study for emotion recognition across all subjects was found to be effective, and its accuracy was 72% (DEAP) and 89% (SEED).
Highlights
Emotion is essential to humans, as it contributes to the communication between people and plays a significant role in rational and intelligent behavior (Picard et al, 2001; Nie et al, 2011), which is critical to several aspects of daily life
The ST-SBSSVM method is an improvement of the sequential backward selection (SBS) method; the two methods were compared
A method is proposed in this paper that can significantly enhance the two-category emotion recognition effect; with a small computational overhead when using the corresponding program to analyze high-dimensional features
Summary
Emotion is essential to humans, as it contributes to the communication between people and plays a significant role in rational and intelligent behavior (Picard et al, 2001; Nie et al, 2011), which is critical to several aspects of daily life. It is difficult to define and classify emotion due to the complex nature and genesis of emotion (Ashforth and Humphrey, 1995; Horlings et al, 2008; Hwang et al, 2018). To classify and represent emotion, several models have been proposed. The first assumes that all emotions can comprise primary emotions, similar to how all colors can comprise primary colors. Plutchik (1962) related eight basic emotions to evolutionarily valuable properties, and reported the following primary emotions: anger, fear, sadness, disgust, surprise, curiosity, acceptance, and joy. Ekman (Power and Dalgleish, 1999; Horlings et al, 2008) reported other
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