基于卷积神经网络的运动图像和SSVEP混合脑机接口

Brain-Apparatus Communication A Journal of Bacomics Pub Date : 2023-10-02 DOI:10.1080/27706710.2023.2258938

Wenwei Luo, Wanguang Yin, Quanying Liu, Youzhi Qu

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引用次数: 0

摘要

基于脑电图(EEG)的脑机接口(BCI)的关键在于神经解码，采用混合脑机接口范式，即融合多种脑机接口范式，可以提高脑机接口解码的准确率。然而，混合脑机接口通常需要对每种范式的脑电信号进行单独的处理过程，这大大降低了脑电信号特征提取的效率和模型的可泛化性。本文提出了一种基于双流卷积神经网络(TSCNN)的混合脑机接口。它结合了稳态视觉诱发电位(SSVEP)和运动意象(MI)范式。TSCNN在训练过程中自动学习提取两种范式下的脑电特征，在测试数据中，与MI模式相比，解码准确率提高了25.4%，与SSVEP模式相比，解码准确率提高了2.6%。此外，TSCNN的多功能性得到了验证，因为它在单模(MI为70.2%，SSVEP为93.0%)和混合模式场景(MI-SSVEP混合场景为95.6%)中都提供了可观的性能。我们的工作将促进基于脑电图的脑机接口系统的实际应用。

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A Hybrid Brain-Computer Interface Using Motor Imagery and SSVEP Based on Convolutional Neural Network

The key to electroencephalography (EEG)-based brain-computer interface (BCI) lies in neural decoding, and its accuracy can be improved by using hybrid BCI paradigms, that is, fusing multiple paradigms. However, hybrid BCIs usually require separate processing processes for EEG signals in each paradigm, which greatly reduces the efficiency of EEG feature extraction and the generalizability of the model. Here, we propose a two-stream convolutional neural network (TSCNN) based hybrid brain-computer interface. It combines steady-state visual evoked potential (SSVEP) and motor imagery (MI) paradigms. TSCNN automatically learns to extract EEG features in the two paradigms in the training process, and improves the decoding accuracy by 25.4% compared with the MI mode, and 2.6% compared with SSVEP mode in the test data. Moreover, the versatility of TSCNN is verified as it provides considerable performance in both single-mode (70.2% for MI, 93.0% for SSVEP) and hybrid-mode scenarios (95.6% for MI-SSVEP hybrid). Our work will facilitate the real-world applications of EEG-based BCI systems.

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