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Multi-Modal Classification Based on Feature Learning of EEG and fNIRS Brain Topographic Map |
He Qun1#, Xu Xiangyuan1, Jiang Guoqian1, Shan Wei2, Tong Yunjie3, Xie Ping1* |
1(Institute of Electric Engineering, Yanshan University, Qinhuangdao 066004, Hebei, China) 2(Library, Yanshan University, Qinhuangdao 066004, Hebei, China) 3(Department of Biomedical Engineering, Purdue University, Indiana 47907, USA) |
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Abstract The brain topographic map can be used to monitor the state of brain activity. In order to accurately extract the spatial characteristics of the signals generated by the brain activity of the subjects and effectively improve the classification accuracy, a multi-modal brain topographic map neural network classification algorithm (MBTMNN) was proposed by combining the brain topographic map and convolutional neural network to classify and recognize motor imagery and mental arithmetic. Firstly, EEG and fNIRS signals were preprocessed to extract the energy characteristics of EEG and the concentration characteristics of oxygenated hemoglobin in fNIRS. The colormap of all samples was unified by combining with the position of each electrode to generate brain topographic maps. The EEG and fNIRS signals were simultaneously input into the convolutional neural network and fused in the feature layer to obtain a training model. The six-fold cross validation experiment was conducted on the 2017 Berlin EEG/fNIRS public dataset. The dataset included 29 subjects, with 300 samples each, in the four classification scenarios of left versus right hand motor imagery, mental arithmetic versus resting state, motor imagery versus mental arithmetic versus resting state, and left versus right hand motor imagery versus mental arithmetic versus resting state, the accuracy rates were 82.91%, 94%, 90.34% and 78.18%, respectively, which were higher than those of recently reported with the same dataset and the state of single mode method. The results indicated that the proposed method effectively fused EEG and fNIRS signals to improve the classification accuracy.
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Received: 13 May 2022
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Corresponding Authors:
* E-mail: pingx@ysu.edu.cn
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About author:: # Member, Chinese Society of Biomedical Engineering |
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