Science and Technology on Electronic Test and Measurement Laboratory, North University of China, Taiyuan 030051, China.
Science and Technology on Electronic Test and Measurement Laboratory, North University of China, Taiyuan 030051, China.
Brain Res. 2024 Oct 15;1841:149085. doi: 10.1016/j.brainres.2024.149085. Epub 2024 Jun 12.
As a cutting-edge technology of connecting biological brain and external devices, brain-computer interface (BCI) exhibits promising applications on extensive fields such as medical and military. As for the disable individuals with four limbs losing the motor functions, it is a potential treatment way to drive mechanical equipments by the means of non-invasive BCI, which is badly depended on the accuracy of the decoded electroencephalogram (EEG) singles. In this study, an explanatory convolutional neural network namely EEGNet based on SimAM attention module was proposed to enhance the accuracy of decoding the EEG singles of index and thumb fingers for both left and right hand using sensory motor rhythm (SMR). An average classification accuracy of 72.91% the data of eight healthy subjects was obtained, which were captured from the one second before finger movement to two seconds after action. Furthermore, the character of event-related desynchronization (ERD) and event related synchronization (ERS) of index and thumb fingers was also studied in this study. These findings have significant importance for controlling external devices or other rehabilitation equipment using BCI in a fine way.
作为连接生物大脑和外部设备的前沿技术,脑机接口(BCI)在医学和军事等广泛领域具有广阔的应用前景。对于四肢丧失运动功能的残疾人来说,通过非侵入性的 BCI 来驱动机械设备是一种潜在的治疗方法,这严重依赖于对 EEG 单个体的解码精度。在这项研究中,提出了一种解释卷积神经网络,即基于 SimAM 注意力模块的 EEGNet,以提高解码左右索引和拇指手指 EEG 单个体的准确性,使用感觉运动节律(SMR)。通过对八名健康受试者的数据进行分析,在手指运动前一秒到运动后两秒的时间段内,得到了平均分类准确率为 72.91%的结果。此外,本研究还研究了索引和拇指手指的事件相关去同步(ERD)和事件相关同步(ERS)的特征。这些发现对于使用 BCI 精细控制外部设备或其他康复设备具有重要意义。
