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Yu-Tsung Hsiao
Graduate Institute of Mechatronic Engineering, National Taipei University of Technology, Taipei 106344, Taiwan

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Journal article
Published: 04 July 2021 in Actuators
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Classification between individuals with mild cognitive impairment (MCI) and healthy controls (HC) based on electroencephalography (EEG) has been considered a challenging task to be addressed for the purpose of its early detection. In this study, we proposed a novel EEG feature, the kernel eigen-relative-power (KERP) feature, for achieving high classification accuracy of MCI versus HC. First, we introduced the relative powers (RPs) between pairs of electrodes across 21 different subbands of 2-Hz width as the features, which have not yet been used in previous MCI-HC classification studies. Next, the Fisher’s class separability criterion was applied to determine the best electrode pairs (five electrodes) as well as the frequency subbands for extracting the most sensitive RP features. The kernel principal component analysis (kernel PCA) algorithm was further performed to extract a few more discriminating nonlinear principal components from the optimal RPs, and these components form a KERP feature vector. Results carried out on 51 participants (24 MCI and 27 HC) show that the newly introduced subband RP feature showed superior classification performance to commonly used spectral power features, including the band power, single-electrode relative power, and also the RP based on the conventional frequency bands. A high leave-one-participant-out cross-validation (LOPO-CV) classification accuracy 86.27% was achieved by the RP feature, using a simple linear discriminant analysis (LDA) classifier. Moreover, with the same classifier, the proposed KERP further improved the accuracy to 88.24%. Finally, cascading the KERP feature to a nonlinear classifier, the support vector machine (SVM), yields a high MCI-HC classification accuracy of 90.20% (sensitivity = 87.50% and specificity = 92.59%). The proposed method demonstrated a high accuracy and a high usability (only five electrodes are required), and therefore, has great potential to further develop an EEG-based computer-aided diagnosis system that can be applied for the early detection of MCI.

ACS Style

Yu-Tsung Hsiao; Chia-Fen Tsai; Chien-Te Wu; Thanh-Tung Trinh; Chun-Ying Lee; Yi-Hung Liu. MCI Detection Using Kernel Eigen-Relative-Power Features of EEG Signals. Actuators 2021, 10, 152 .

AMA Style

Yu-Tsung Hsiao, Chia-Fen Tsai, Chien-Te Wu, Thanh-Tung Trinh, Chun-Ying Lee, Yi-Hung Liu. MCI Detection Using Kernel Eigen-Relative-Power Features of EEG Signals. Actuators. 2021; 10 (7):152.

Chicago/Turabian Style

Yu-Tsung Hsiao; Chia-Fen Tsai; Chien-Te Wu; Thanh-Tung Trinh; Chun-Ying Lee; Yi-Hung Liu. 2021. "MCI Detection Using Kernel Eigen-Relative-Power Features of EEG Signals." Actuators 10, no. 7: 152.

Journal article
Published: 24 July 2014 in Sensors
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Electroencephalogram-based emotion recognition (EEG-ER) has received increasing attention in the fields of health care, affective computing, and brain-computer interface (BCI). However, satisfactory ER performance within a bi-dimensional and non-discrete emotional space using single-trial EEG data remains a challenging task. To address this issue, we propose a three-layer scheme for single-trial EEG-ER. In the first layer, a set of spectral powers of different EEG frequency bands are extracted from multi-channel single-trial EEG signals. In the second layer, the kernel Fisher’s discriminant analysis method is applied to further extract features with better discrimination ability from the EEG spectral powers. The feature vector produced by layer 2 is called a kernel Fisher’s emotion pattern (KFEP), and is sent into layer 3 for further classification where the proposed imbalanced quasiconformal kernel support vector machine (IQK-SVM) serves as the emotion classifier. The outputs of the three layer EEG-ER system include labels of emotional valence and arousal. Furthermore, to collect effective training and testing datasets for the current EEG-ER system, we also use an emotion-induction paradigm in which a set of pictures selected from the International Affective Picture System (IAPS) are employed as emotion induction stimuli. The performance of the proposed three-layer solution is compared with that of other EEG spectral power-based features and emotion classifiers. Results on 10 healthy participants indicate that the proposed KFEP feature performs better than other spectral power features, and IQK-SVM outperforms traditional SVM in terms of the EEG-ER accuracy. Our findings also show that the proposed EEG-ER scheme achieves the highest classification accuracies of valence (82.68%) and arousal (84.79%) among all testing methods.

ACS Style

Yi-Hung Liu; Chien-Te Wu; Wei-Teng Cheng; Yu-Tsung Hsiao; Po-Ming Chen; Jyh-Tong Teng. Emotion Recognition from Single-Trial EEG Based on Kernel Fisher’s Emotion Pattern and Imbalanced Quasiconformal Kernel Support Vector Machine. Sensors 2014, 14, 13361 -13388.

AMA Style

Yi-Hung Liu, Chien-Te Wu, Wei-Teng Cheng, Yu-Tsung Hsiao, Po-Ming Chen, Jyh-Tong Teng. Emotion Recognition from Single-Trial EEG Based on Kernel Fisher’s Emotion Pattern and Imbalanced Quasiconformal Kernel Support Vector Machine. Sensors. 2014; 14 (8):13361-13388.

Chicago/Turabian Style

Yi-Hung Liu; Chien-Te Wu; Wei-Teng Cheng; Yu-Tsung Hsiao; Po-Ming Chen; Jyh-Tong Teng. 2014. "Emotion Recognition from Single-Trial EEG Based on Kernel Fisher’s Emotion Pattern and Imbalanced Quasiconformal Kernel Support Vector Machine." Sensors 14, no. 8: 13361-13388.