计算机科学
深度学习
人工智能
脑-机接口
脑电图
软件部署
机器学习
接口(物质)
特征提取
人工神经网络
特征(语言学)
神经康复
深层神经网络
循环神经网络
测距
特征学习
信号(编程语言)
解码方法
人机交互
任务(项目管理)
模式识别(心理学)
作者
Yizhen Li,Enze Chen,Xiaolin Xiao,Minpeng Xu,Ming Dong
标识
DOI:10.1088/1741-2552/ae2717
摘要
Brain-computer interface (BCI) technology enables direct communication between the human brain and external devices by decoding electroencephalography (EEG)signals into actionable commands. As a noninvasive and portable modality, EEG-based BCIs hold promise for applications ranging from neurorehabilitation to assistive technologies. However, their performance depends critically on the accurate extraction of relevant neural features and the reliable recognition of underlying patterns. Deep learning has transformed this process. By automatically learning complex, task-relevant representations from raw or minimally processed EEG data, deep neural networks have surpassed many traditional handcrafted feature approaches in both accuracy and adaptability. Yet, the substantial computational and memory demands of many deep learning architectures limit their deployment in portable or real-time BCI systems. This challenge has motivated a growing interest in lightweight models-architectures optimized to reduce complexity while preserving or even enhancing performance. This paper provides a systematic review of such lightweight deep learning models for EEG signal classification. To organize this landscape, existing approaches are categorized into three main strategies: (1) information integration strategies based on multi-scale feature fusion, (2) hidden layer optimization strategies, and (3) hybrid improvement strategies based on structural optimization. The review synthesizes recent advances, identifies emerging trends, and outlines potential directions for future research. These insights aim to inform the design of efficient and robust EEG classification architectures capable of meeting the practical demands of real-world BCI applications.
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