Improving EEG Classification Through Randomly Reassembling Original and Generated Data with Transformer-based Diffusion Models

TL;DR

This paper introduces a Transformer-based diffusion model for EEG data augmentation, reassembling generated and original signals to significantly improve classification accuracy across multiple datasets.

Contribution

It proposes a novel diffusion model with specialized preprocessing and modules, enhancing EEG data quality and classification performance beyond existing methods.

Findings

Achieved up to 14% accuracy improvement on the Bonn dataset

Demonstrated effectiveness across four diverse EEG datasets

Enhanced data quality with a new reassembly augmentation technique

Abstract

Electroencephalogram (EEG) classification has been widely used in various medical and engineering applications, where it is important for understanding brain function, diagnosing diseases, and assessing mental health conditions. However, the scarcity of EEG data severely restricts the performance of EEG classification networks, and generative model-based data augmentation methods have emerged as potential solutions to overcome this challenge. There are two problems with existing methods: (1) The quality of the generated EEG signals is not high; (2) The enhancement of EEG classification networks is not effective. In this paper, we propose a Transformer-based denoising diffusion probabilistic model and a generated data-based augmentation method to address the above two problems. For the characteristics of EEG signals, we propose a constant-factor scaling method to preprocess the signals, which reduces the loss of information. We incorporated Multi-Scale Convolution and Dynamic Fourier Spectrum Information modules into the model, improving the stability of the training process and the quality of the generated data. The proposed augmentation method randomly reassemble the generated data with original data in the time-domain to obtain vicinal data, which improves the model performance by minimizing the empirical risk and the vicinal risk. We verify the proposed augmentation method on four EEG datasets for four tasks and observe significant accuracy performance improvements: 14.00% on the Bonn dataset; 6.38% on the SleepEDF-20 dataset; 9.42% on the FACED dataset; 2.5% on the Shu dataset. We will make the code of our method publicly accessible soon.