A Modified Transformer Network for Seizure Detection Using EEG Signals.

Wenrong Hu, Juan Wang, Feng Li, Daohui Ge, Yuxia Wang, Qingwei Jia, Shasha Yuan
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Abstract

Seizures have a serious impact on the physical function and daily life of epileptic patients. The automated detection of seizures can assist clinicians in taking preventive measures for patients during the diagnosis process. The combination of deep learning (DL) model with convolutional neural network (CNN) and transformer network can effectively extract both local and global features, resulting in improved seizure detection performance. In this study, an enhanced transformer network named Inresformer is proposed for seizure detection, which is combined with Inception and Residual network extracting different scale features of electroencephalography (EEG) signals to enrich the feature representation. In addition, the improved transformer network replaces the existing Feedforward layers with two half-step Feedforward layers to enhance the nonlinear representation of the model. The proposed architecture utilizes discrete wavelet transform (DWT) to decompose the original EEG signals, and the three sub-bands are selected for signal reconstruction. Then, the Co-MixUp method is adopted to solve the problem of data imbalance, and the processed signals are sent to the Inresformer network for seizure information capture and recognition. Finally, discriminant fusion is performed on the results of three-scale EEG sub-signals to achieve final seizure recognition. The proposed network achieves the best accuracy of 100% on Bonn dataset and the average accuracy of 98.03%, sensitivity of 95.65%, and specificity of 98.57% on the long-term CHB-MIT dataset. Compared to the existing DL networks, the proposed method holds significant potential for clinical research and diagnosis applications with competitive performance.

利用脑电信号检测癫痫发作的改良变压器网络
癫痫发作严重影响癫痫患者的身体功能和日常生活。癫痫发作的自动检测可以帮助临床医生在诊断过程中为患者采取预防措施。将深度学习(DL)模型与卷积神经网络(CNN)和变压器网络相结合,可有效提取局部和全局特征,从而提高癫痫发作检测性能。本研究针对癫痫发作检测提出了一种名为 Inresformer 的增强型变压器网络,该网络与提取脑电图(EEG)信号不同尺度特征的 Inception 和 Residual 网络相结合,丰富了特征表示。此外,改进后的变压器网络用两个半步前馈层取代了现有的前馈层,以增强模型的非线性表示。提议的架构利用离散小波变换(DWT)对原始脑电信号进行分解,并选择三个子带进行信号重建。然后,采用 Co-MixUp 方法解决数据不平衡问题,并将处理后的信号发送到 Inresformer 网络,以捕获和识别癫痫发作信息。最后,对三尺度脑电图子信号的结果进行判别融合,以实现最终的癫痫发作识别。所提出的网络在波恩数据集上达到了 100% 的最佳准确率,在长期 CHB-MIT 数据集上的平均准确率为 98.03%,灵敏度为 95.65%,特异性为 98.57%。与现有的 DL 网络相比,所提出的方法在临床研究和诊断应用中具有巨大的潜力,其性能极具竞争力。
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