A Channel-Fused Dense Convolutional Network for EEG-Based Emotion Recognition

Human emotion recognition could greatly contribute to human-computer interaction with promising applications in artificial intelligence. One of the challenges in recognition tasks is learning effective representations with stable performances from electroencephalogram (EEG) signals. In this article, we propose a novel deep-learning framework, named channel-fused dense convolutional network, for EEG-based emotion recognition. First, we use a 1-D convolution layer to receive weighted combinations of contextual features along the temporal dimension from EEG signals. Next, inspired by state-of-the-art object classification techniques, we employ 1-D dense structures to capture electrode correlations along the spatial dimension. The developed algorithm is capable of handling temporal dependencies and electrode correlations with the effective feature extraction from noisy EEG signals. Finally, we perform extensive experiments based on two popular EEG emotion datasets. Results indicate that our framework achieves prominent average accuracies of 90.63% and 92.58% on the SEED and DEAP datasets, respectively, which both receive better performances than most of the compared studies. The novel model provides an interpretable solution with excellent generalization capacity for broader EEG-based classification tasks.

Automated summary

This article introduces a novel deep learning framework, the channel-fused dense convolutional network, for EEG-based emotion recognition, capable of effectively extracting features from noisy EEG signals. Experimental results show that the framework achieved significant accuracies on the SEED and DEAP datasets, outperforming most comparative studies.