脑机通信与慢皮层电位

Brain-computer communication and slow cortical potentials.

作者信息

Hinterberger Thilo, Schmidt Stefan, Neumann Nicola, Mellinger Jürgen, Blankertz Benjamin, Curio Gabriel, Birbaumer Niels

机构信息

Institute of Medical Psychology and Behavioral Neurobiology, University of Tübingen, 72076 Tübingen, Germany.

出版信息

IEEE Trans Biomed Eng. 2004 Jun;51(6):1011-8. doi: 10.1109/TBME.2004.827067.

DOI:10.1109/TBME.2004.827067

PMID:15188872

Abstract

A thought translation device (TTD) has been designed to enable direct brain-computer communication using self-regulation of slow cortical potentials (SCPs). However, accuracy of SCP control reveals high intersubject variability. To guarantee the highest possible communication speed, some important aspects of training SCPs are discussed. A baseline correction of SCPs can increase performance. Multichannel recordings show that SCPs are of highest amplitude around the vertex electrode used for feedback, but in some subjects more global distributions were observed. A new method for control of eye movement is presented. Sequential effects of trial-to-trial interaction may also cause difficulties for the user. Finally, psychophysiological factors determining SCP communication are discussed.

摘要

一种思维翻译设备（TTD）已被设计出来，用于通过慢皮层电位（SCP）的自我调节实现直接的脑机通信。然而，SCP控制的准确性显示出个体间的高度变异性。为了保证尽可能高的通信速度，讨论了训练SCP的一些重要方面。SCP的基线校正可以提高性能。多通道记录表明，SCP在用于反馈的头顶电极周围幅度最高，但在一些受试者中观察到更广泛的分布。提出了一种控制眼球运动的新方法。逐次试验交互的顺序效应也可能给用户带来困难。最后，讨论了决定SCP通信的心理生理因素。

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脑机通信与慢皮层电位

Brain-computer communication and slow cortical potentials.

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