基于视角-规则的深度TSK模糊分类器及其在多元癫痫脑电信号识别中的应用

在癫痫脑电信号分类检测中,传统机器学习方法分类效果不理想,深度学习模型虽然具有较好的特征学习优势,但其“黑盒”学习方式不具备可解释性,不能很好地应用于临床辅助诊断;并且,现有的多视角深度TSK模糊系统难以有效表征各视角特征之间的相关性.针对以上问题,提出一种基于视角-规则的深度Takagi-SugenoKang (TSK)模糊分类器(view-to-rule Takagi-Sugeno-Kang fuzzy classifier, VR-TSK-FC),并将其应用于多元癫痫脑电信号检测中.该算法在原始数据上构建前件规则以保证模型的可解释性,利用一维卷积神经网络(1-dimensional convolutional neural network, 1D-CNN)从多角度抓取多元脑电信号深度特征.每个模糊规则的后件部分分别采用一个视角的脑电信号深度特征作为其后件变量,视角-规则的学习方式提高了VR-TSK-FC表征能力.在Bonn和CHB-MIT数据集上, VR-TSK-FC算法模糊逻辑推理过程保证可解释的基础上达到了较好分类效果.     

基于微状态方法的癫痫脑电信号识别研究

目的 癫痫发作时脑神经元异常放电,严重危及人的生命,准确识别癫痫脑电信号对癫痫诊断具有重大意义,对此使用微状态分析法对癫痫脑电信号进行识别研究。方法 各选取11名癫痫患者和健康人,计算癫痫发作、未发作和健康人脑电微状态的传统特征（出现频率、平均持续时间、覆盖率和转移概率）、Hurst指数、动态特征（ACF和AIF）,进行差异性分析并使用SVM进行分类。结果1-40 Hz,癫痫发作和健康人、癫痫发作和未发作、癫痫未发作和健康人的传统特征、Hurst指数、动态特征均有显著差异,三种特征融合的准确率分别为99.9%、96.3%、96.3%,均高于其它频带（delta、theta、alpha、beta和 gamma）的准确率。结论 癫痫脑电微状态特征能被准确识别,1-40 Hz多参数特征融合能有效提高分类准确率。     

基于同步压缩和DCGAN的癫痫脑电信号检测方法

脑电信号智能识别是癫痫病检测的重要手段,为更加准确地预测癫痫发作,针对目前的深度学习方法特别是卷积神经网络在脑电信号分类方面存在的一些问题,如算法复杂度过高、样本量太少导致分类效果差等,提出基于傅里叶同步压缩变换和深度卷积生成对抗网络的癫痫脑电信号检测方法。首先同步压缩方法将短时傅里叶变换处理后的信号时频能量进行压缩,使得频谱图像精度更高;其次构建深度卷积生成对抗网络来提取特征;最后实现癫痫发作预测。实验在CHB-MIT脑电数据集上进行,结果表明该方法具有97.9%的检测准确率。使用生成对抗网络有效解决了样本量不足的问题,结合同步压缩处理方法后,具有良好的识别准确性。     

基于增强深度特征和TSK模糊分类器的癫痫脑电信号识别

识别癫痫脑电信号的关键在于获取有效的特征和构建可解释的分类器.为此,提出一种基于增强深度特征的TSK模糊分类器(ED-TSK-FC).首先,ED-TSK-FC使用一维卷积神经网络(1D-CNN)自动获取癫痫脑电信号的深度特征与潜在类别信息,并将深度特征和潜在类别信息合并为增强深度特征;其次,将增强深度特征作为ED-TSK-FC模糊规则前件与后件部分的训练变量,保证原始输入的深度特征及其潜在意义都出现在模糊规则中,进而对增强深度特征作出良好的解释;然后,采用岭回归极限学习算法对模糊规则的后件参数进行快速求解,在不显著降低分类准确度的情况下,ED-TSK-FC的廉价训练方法可以缩短模型的训练时间;最后,在Bonn癫痫数据集上,分别从分类性能、学习效率和可解释性3个方面,验证ED-TSK-FC的优越性.     

基于脑电多特征融合的癫痫发作预测方法

癫痫的发作会给患者的身体和精神造成极大的创伤,对癫痫发作的准确预测可以及时协助医生对患者采取治疗措施.为了准确预测癫痫发作,提出脑电特征和多通道脑电交互特征相融合的癫痫发作预测方法.首先,提出多尺度符号化排列传递熵对多通道脑电信号交互信息进行分析,生成同步矩阵,并通过显著性分析筛选与癫痫发作相关的重要脑电通道,减少不必要特征对分类的干扰;然后,对筛选通道后的脑电信号生成表征脑电信号特征的功率谱密度能量图(PSDED)和描述脑通道交互特征的同步矩阵图(SMD),将两个特征图融合,采用深度卷积神经网络(DCNN)对癫痫患者脑电信号进行分类识别,提高学习能力和泛化能力,分类准确率可达到96.825%;最后,在分类的基础上采用预测评价系统对癫痫发作预测性能进行评估,癫痫发作预测范围(SPH)为10 min和发作发生期(SOP)为10 min时,预测敏感性达到96.66%,误检率可达到0.03/h;当SPH为30min,SOP为10 min时,预测敏感性达到93.17%,误检率可达到0.05/h.与现有研究结果相比较,所提出方法具有较好的预测敏感度和较低的误检率.     

基于邻接矩阵分解的脑电特征提取与分类方法

针对脑-机接口研究中运动想象脑电信号的特征提取问题,本文提出了一种基于脑功能网络邻接矩阵分解的新方法。首先采用多通道运动想象脑电信号构建脑功能网络,然后对相应的邻接矩阵进行奇异值分解,依据矩阵奇异值特征向量定义了脑电的特征参数,最后输入支持向量机分类器,对BCI Competition IV Data Sets 1中的四组数据进行分类识别。实验结果表明,基于脑功能网络邻接矩阵分解的特征提取和支持向量机分类器的方法能够以较高识别率区分不同的运动想象任务,为脑电特征提取研究提供了新的思路。     

基于便携式脑电设备的快乐和悲伤情绪分类

驾驶员情绪状态的识别对车辆主动安全技术的研究具有重要的应用价值.本研究通过情绪视频诱发的方法采集17位被试前额双通道脑电信号,提取不同情绪的脑电特征,并对数据进行降维处理后采用多种分类器进行情绪分类.结果显示,与单核分类器和集成学习分类器相比,基于梯度提升决策树（GBDT）算法得到快乐和悲伤的识别准确率最高.本研究为驾驶员情绪状态的实时监测和识别提供新方法,为提高行车的安全性提供了理论保障.     

基于SVM和小波分析的脑电信号分类方法

根据癫痫脑电信号与正常脑电信号波形和能量特征的不同,研究了两种的脑电信号分类方法,一种采用支持向量机SVM(Support Vector Machines)分类器对正常脑电和癫痫脑电进行分类;另一种使用小波分析和支持向量机相结合的方法对脑电进行分类,并比较了这两种方法对正常脑电和癫痫脑电分类的正确率。实验结果表明,小波分析和SVM结合的方法对脑电信号分类可以取得更好的效果,能有效区分癫痫脑电和正常脑电。     

基于小波系数特征融合的小鼠癫痫脑电分类

采集癫痫小鼠模型在常态与致癫状态下的脑电信号以研究其癫痫脑电的自动分类。对经过噪声和伪迹消除预处理的脑电信号进行小波变换,获得不同频率子带的小波系数,对脑电信号及与癫痫特征波相关的小波系数提取相应的线性特征（标准差）和非线性特征（样本熵）;基于这些特征及其组合使用支持向量机分类器实现分类。实验发现基于小鼠脑电本身的标准差和样本熵的分类正确率分别为59.10%和58.00%;而融合各相关小波系数的标准差或样本熵,分类正确率分别达到86.60%和88.60%;融合全部相关小波系数的线性和非线性特征后分类正确率为99.80%。这些结果说明基于小波系数特征融合的分类算法性能有显著提升,能有效实现小鼠癫痫脑电的自动分类。     

基于小波包分解和遗传神经网络的癫痫识别

基于小波包分解和遗传神经网络对正常脑电和癫痫脑电进行识别。通过分析脑电数据找出信号特征;利用一维离散小波包分解提取含有识别特征的脑电信号频率段,并以脑电各频段的相对能量作为信号特征;然后建立基于遗传算法优化的BP网络,用于对癫痫脑电识别。实验结果表明,该方法可以有效提取信号特征,并且对信号进行准确的识别。     

Combined neural network model employing wavelet coefficients for EEG signals classification

This paper illustrates the use of combined neural network model to guide model selection for classification of electroencephalogram (EEG) signals. The EEG signals were decomposed into time–frequency representations using discrete wavelet transform and statistical features were calculated to depict their distribution. The first-level networks were implemented for the EEG signals classification using the statistical features as inputs. To improve diagnostic accuracy, the second-level networks were trained using the outputs of the first-level networks as input data. Three types of EEG signals (EEG signals recorded from healthy volunteers with eyes open, epilepsy patients in the epileptogenic zone during a seizure-free interval, and epilepsy patients during epileptic seizures) were classified with the accuracy of 94.83% by the combined neural network. The combined neural network model achieved accuracy rates which were higher than that of the stand-alone neural network model.     

EEG signal classification using wavelet feature extraction and a mixture of expert model

Mixture of experts (ME) is modular neural network architecture for supervised learning. A double-loop Expectation-Maximization (EM) algorithm has been introduced to the ME network structure for detection of epileptic seizure. The detection of epileptiform discharges in the EEG is an important component in the diagnosis of epilepsy. EEG signals were decomposed into the frequency sub-bands using discrete wavelet transform (DWT). Then these sub-band frequencies were used as an input to a ME network with two discrete outputs: normal and epileptic. In order to improve accuracy, the outputs of expert networks were combined according to a set of local weights called the “gating function”. The invariant transformations of the ME probability density functions include the permutations of the expert labels and the translations of the parameters in the gating functions. The performance of the proposed model was evaluated in terms of classification accuracies and the results confirmed that the proposed ME network structure has some potential in detecting epileptic seizures. The ME network structure achieved accuracy rates which were higher than that of the stand-alone neural network model.     

脑磁图脑功能连接网络癫痫棘波识别方法研究

脑磁图（MEG）现在被广泛用于临床检查及很多领域的医学研究中,基于静息态的脑磁图脑网络分析能用于研究大脑生理或病理机制。脑磁图分析对癫痫疾病的诊断具有重要的参考价值。对癫痫脑磁信号的自动分类可以及时对患者的情况作出判断,在临床上有很重要的意义。现有文献中对癫痫脑电信号的自动分类方法的研究已比较充分,但对癫痫脑磁信号的研究比较薄弱。提出了一种基于脑功能连接网络的全频段机器学习癫痫脑磁棘波信号自动判别方法,对四种分类器进行了综合判别对比,选择了效果最优的分类器,判别准确率可达到93.8%。因此,该方法在脑磁图癫痫棘波的自动识别与标记方面有较好的应用前景。     

采用多路图注意力网络的情绪脑电信号识别方法

情绪是一种大脑产生的主观认知的概括。脑信号解码技术可以以一种较客观的方式来有效地研究人的情绪及其相关认知行为。本文提出了一种基于图注意力网络的脑电情绪识别方法(multi-path graph attention networks, MPGAT),该方法通过对脑电信号通道建图,利用卷积层提取脑电信号的时域特征以及各频带的特征,使用图注意力网络进一步捕捉情绪脑电信号的局部特征以及各脑区之间的内在功能关系,进而构建出更好的脑电信号表征。MPGAT在SEED和SEED-IV数据集的跨被试情绪识别平均准确率分别为86.03%、72.71%,在DREAMER数据集的效价(valence)和唤醒(arousal)维度的跨被试平均准确率分别为76.35%和75.46%,达到并部分超过了目前最先进脑电情绪识别方法的性能。本文所提出的脑电信号处理方法有望为情绪认知科学研究与情绪脑机接口系统提供新的技术手段。     

Prediction of epileptic seizures from spectral features of intracranial eeg recordings using deep learning approach

Epilepsy is a prevalent neurological disorder, which disturbs the lives of millions of people worldwide owing to the onset of abrupt seizures. The forecasting of seizures could help in protecting their lives by alerts or in clinical operations during epilepsy surgeries. The present paper addresses this problem by proposing a deep learning framework for prediction of epileptic seizures using intracranial EEG (iEEG) recordings. This framework performs filtering and segmentation of iEEG signals into 10s, 20s, 30s, 40s, 50s and 60s duration segments. These segments are further resolved into eight distinct spectral bands corresponding to delta, theta, alpha, beta and gamma sub-bands with frequency-domain transformation. Then, mean amplitude and band power features are extracted from each band, which are provided to convolutional neural network (CNN) and long short-term memory network (LSTM) algorithms for classification. The simulation results of the proposed CNN model exhibit higher performance with average accuracy, sensitivity, specificity, AUC and F1 score of 94.74%, 95.8%, 94.46%, 95.13% and 94.75% respectively for iEEG segments of 40s duration. Thus, the performance analysis and comparison with existing literature unveil that the proposed CNN model is an optimal approach for accurate and real-time prediction of epileptic seizures.

     

Emotion recognition using EEG signals with relative power values and Bayesian network

Many researchers use electroencephalograms (EEGs) to study brain activity in the context of seizures, epilepsy, and lie detection. It is desirable to eliminate EEG artifacts to improve signal collection. In this paper, we propose an emotion recognition system for human brain signals using EEG signals. We measure EEG signals relating to emotion, divide them into five frequency ranges on the basis of power spectrum density, and eliminate low frequencies from 0 to 4 Hz to eliminate EEG artifacts. The resulting calculations of the frequency ranges are based on the percentage of the selected range relative to the total range. The calculated values are then compared to standard values from a Bayesian network, calculated from databases. Finally, we show the emotion results as a human face avatar.