脑电图
计算机科学
线性判别分析
人工智能
模式识别(心理学)
运动表象
适应(眼睛)
判别式
相似性(几何)
机器学习
语音识别
领域(数学分析)
约束(计算机辅助设计)
最大化
一般化
核(代数)
支持向量机
领域(数学)
面子(社会学概念)
脑-机接口
域适应
适应性
相互信息
管道(软件)
不变(物理)
灵活性(工程)
分割
主成分分析
特征提取
面部识别系统
判别式
信号(编程语言)
上下文图像分类
频域
作者
Yifan Gong,Kaiting Shi,Xiaolong Niu,Lijun Yang,Xiaohui Yang,Zheng Chen
标识
DOI:10.1109/jbhi.2025.3610446
摘要
Electroencephalography (EEG) has emerged as a widely utilized signal in motor imagery (MI) brain-computer interfaces(BCI) due to its convenience and safety. Recently, deep learning methods have rapidly developed in the field of brain computer interfaces. However, traditional EEG classification methods often face challenges related to limited generalization capability across subjects. To address this issue, this paper proposes a multi-source discriminant dynamic domain adaptation model(MSD-DDA) aimed at fully leveraging domain adaptation to enhance the accuracy of motor imagery classification. The model adeptly handles global and local disparities in motor imagery classification by dynamically minimizing differences between global domain and local subdomain. Furthermore, to ensure discriminability and diversity in the target domain, we introduce batch kernel norm maximization of the difference, thereby enhancing the model's discriminability in the target domain while preserving prediction diversity. To tackle variations in similarity between different source domains and the target domain, we devise a weighted joint prediction mechanism. This mechanism automatically adjusts the contribution weight of each source domain based on its similarity to the target domain, facilitating more precise discriminant prediction and improved adaptability to scenarios with multiple source domains. To evaluate our approach, we conducted a large number of experiments on datasets 1 and 2a of the Fourth BCI Competition and on the openBMI dataset, with average classification accuracy of 92.43%, 79.24% and 71.96%, respectively.Finally, we compare the proposed method with several classical and recent algorithms, and prove that its performance is better than the existing methods.
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