基于梯度惩罚的 Wasserstein 生成对抗网络和卷积神经网络的运动图像脑电图分类。

Hui Xiong, Jiahe Li, Jinzhen Liu, Jinlong Song, Yuqing Han
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引用次数: 0

摘要

目的:由于难以获得运动图像脑电图(MI-EEG)数据并确保其质量,训练数据不足往往导致基于深度学习的分类网络过度拟合和泛化能力不足。因此,我们提出了一种新颖的数据增强方法和深度学习分类模型,以进一步提高 MI-EEG 的解码性能。通过连续小波变换,将原始脑电信号转换成时频图,作为模型的输入。提出了一种改进的 Wasserstein 生成对抗网络与梯度惩罚数据增强方法,有效地扩展了用于模型训练的数据集。此外,还设计了一个简洁高效的深度学习模型,以进一步提高解码性能。通过多种数据评估方法的验证,证明了所提出的生成网络可以生成更真实的数据。在 BCI Competition IV 2a 和 2b 数据集以及实际收集的数据集上的实验结果表明,分类准确率分别为 83.4%、89.1% 和 73.3%,Kappa 值分别为 0.779、0.782 和 0.644。结果表明,所提出的模型优于最先进的方法。实验结果表明,该方法有效地增强了 MI-EEG 数据,减轻了分类网络的过拟合,提高了 MI 分类的准确性,对 MI 任务具有积极意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wasserstein generative adversarial network with gradient penalty and convolutional neural network based motor imagery EEG classification.

Objective.Due to the difficulty in acquiring motor imagery electroencephalography (MI-EEG) data and ensuring its quality, insufficient training data often leads to overfitting and inadequate generalization capabilities of deep learning-based classification networks. Therefore, we propose a novel data augmentation method and deep learning classification model to enhance the decoding performance of MI-EEG further.Approach.The raw EEG signals were transformed into the time-frequency maps as the input to the model by continuous wavelet transform. An improved Wasserstein generative adversarial network with gradient penalty data augmentation method was proposed, effectively expanding the dataset used for model training. Additionally, a concise and efficient deep learning model was designed to improve decoding performance further.Main results.It has been demonstrated through validation by multiple data evaluation methods that the proposed generative network can generate more realistic data. Experimental results on the BCI Competition IV 2a and 2b datasets and the actual collected dataset show that classification accuracies are 83.4%, 89.1% and 73.3%, and Kappa values are 0.779, 0.782 and 0.644, respectively. The results indicate that the proposed model outperforms state-of-the-art methods.Significance.Experimental results demonstrate that this method effectively enhances MI-EEG data, mitigates overfitting in classification networks, improves MI classification accuracy, and holds positive implications for MI tasks.

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