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引用次数: 6
摘要
脑机接口(bmi)使人类能够通过调节大脑信号来控制设备。由于目前的BMI技术有几个障碍需要克服,需要探索大脑活动的其他来源。与自上而下的认知功能相关的大脑活动似乎可以在bmi领域开辟新的前景。由于自上而下的认知bmi可以利用来自更多样化网络的神经信号,具有复杂隐藏层的深度学习方法可能提供更优化的解码性能。本研究采用自顶向下稳态视觉诱发电位(SSVEP)范式(N = 20),发现具有s型激活函数的深度学习算法的解码准确率(48.42%)显著高于具有收缩(42.52%)的正则化线性判别分析(rLDA);T (19) = - 3.183, p < 0.01),在我们之前的研究中使用。因此,在自上而下的认知BMI范式中,深度学习方法似乎更适合分类。
Brain-machine interfaces (BMIs) enable humans to control devices by modulating their brain signals. As the current BMI technology has several obstacles to overcome, additional sources of brain activity need to be explored. It seems plausible that the brain activity associated with top-down cognitive functions could open a new prospect in the field of BMIs. As top-down cognitive BMIs could exploit neural signals from more diverse networks, a deep-learning approach with complex hidden layers may provide a more optimal decoding performance. In this study, using our top-down steady-state visual evoked potential (SSVEP) paradigm (N = 20), we observed that the decoding accuracy (48.42%) of a deep-learning algorithm with a sigmoid activation function was significantly higher than that of regularized linear discriminant analysis (rLDA) with shrinkage (42.52%; t(19) = −3.183, p < 0.01), used in our previous study. Therefore, a deep-learning approach seems to be more optimized for classification in the top-down cognitive BMI paradigm.
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