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Abstract
Electroencephalogram (EEG)-based emotion recognition (ER) has drawn increasing attention in the brain–computer interface (BCI) due to its great potentials in human–machine interaction applications. According to the characteristics of rhythms, EEG signals usually can be divided into several different frequency bands. Most existing methods concatenate multiple frequency band features together and treat them as a single feature vector. However, it is often difficult to utilize band-specific information in this way. In this study, an optimized projection and Fisher discriminative dictionary learning (OPFDDL) model is proposed to efficiently exploit the specific discriminative information of each frequency band. Using subspace projection technology, EEG signals of all frequency bands are projected into a subspace. The shared dictionary is learned in the projection subspace such that the specific discriminative information of each frequency band can be utilized efficiently, and simultaneously, the shared discriminative information among multiple bands can be preserved. In particular, the Fisher discrimination criterion is imposed on the atoms to minimize within-class sparse reconstruction error and maximize between-class sparse reconstruction error. Then, an alternating optimization algorithm is developed to obtain the optimal solution for the projection matrix and the dictionary. Experimental results on two EEG-based ER datasets show that this model can achieve remarkable results and demonstrate its effectiveness.
Highlights
Brain–computer interface (BCI) has been one of the research hotspots in recent years in health monitoring and biomedicine (Edgar et al, 2020; Ni et al, 2020b)
In most cases, the SDs of all methods are small in all five bands. It demonstrates that multiple bands are helpful for EEG-based emotion recognition (ER), due to that the features of each band have discrimination ability and five bands are complementary for distinguishing EEG emotions
We verified the performance of optimized projection and Fisher discriminative dictionary learning (OPFDDL) according to valence, arousal, and dominance
Summary
Brain–computer interface (BCI) has been one of the research hotspots in recent years in health monitoring and biomedicine (Edgar et al, 2020; Ni et al, 2020b). Barthélemy et al (2013) developed an efficient method to represent EEG signals based on the adapted Gabor dictionary and demonstrated on real data that the learned multivariate model is flexible and the learned representation is informative and interpretable. Kashefpoor et al (2019) developed a correlational label consistent K-SVD dictionary learning method applied to EEG-based screening tool. After the success of dictionary learning, in this study, we propose optimized projection and Fisher discriminative dictionary learning (DDL) for EEG-based ER. (4) These extensive experiments on the SEED and DREAMER datasets demonstrate that the multiple band collaborative learning is effective, and this method can improve the discrimination ability of sparse coding in EEG-based ER
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