Abstract
Transfer learning is an approach in machine learning where a model that was built and trained on one task is re-purposed on a second task. The success of transfer learning in computer vision has motivated its use in neuroscience. Although common in image recognition, the use of transfer learning in EEG classification remains unexplored. Most EEG-based neuroscience studies depend on using traditional machine learning algorithms to answer a question, rather than on improving the algorithms. Developing algorithms for transfer learning for EEG can also assist with problems of low data availability in EEG classification. The primary objective of this study is to investigate EEG-based transfer learning and propose deep transfer learning models to transfer knowledge from emotion recognition to preference recognition to enhance the classification prediction accuracy. To the best of our knowledge, this is the first study demonstrating the effect of applying deep transfer learning between EEG-based emotion recognition and EEG-based preference detection. We propose different approaches for deep transfer learning models to detect preferences from EEG signals using the preprocessed DEAP dataset. Two types of features were extracted from EEG signals, namely the power spectral density and valence. We built three models of deep neural networks: basic without transfer learning, fine-tuning of deep transfer learning, and retraining of deep transfer learning. We compared the performance of deep transfer learning with those of deep neural networks and other conventional classification algorithms such as support vector machine, random forest, and k-nearest neighbor. Although the deep neural network classifiers achieved a high accuracy of greater than 87%, deep transfer learning achieved the highest accuracy result of 93%. The results demonstrate that although the proposed deep transfer learning approaches exhibit higher accuracy than the support vector machine and k-nearest neighbor classifiers, random forest achieves results similar to those of deep transfer learning.
Highlights
Human variability induces a variability in the related EEG across subjects or sessions and even time within a subject
We mainly investigated the relationship between EEG classification of preference and emotion at a very deep level. we compared the performance of deep learning with deep neural networks (DNNs) and other conventional classification algorithms such as support vector machine (SVM), random forest (RF), and k-nearest neighbor (KNN)
This study investigated the application of machine learning and computational statistics in consumer preference prediction using the different DNN, RF, KNN, and SVM classification algorithms
Summary
Human variability induces a variability in the related EEG across subjects or sessions and even time within a subject. The performance of a classifier trained on a particular task, session, or subject, depending on the information acquired while learning a related task [1]–[3]. Most research on TL in BCIs focused on the transfer of the information across subjects or sessions, but task TL remains mostly unexplored [3]. According to a recent review [3], there have been no studies reported on task TL in affective BCIs that identify emotion or preferences from EEG. Our primary objective is to investigate EEG-based TL and propose deep transfer learning (DTL) model to transfer knowledge from emotion recognition to preference recognition with the aim of enhancing the accuracy of classification prediction. The main research questions of this study were as follows: How can knowledge be transferred between the emotion domain and the preference domain?
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