通过将脑电图和眼动追踪相结合来增强脑机接口（BCIs）对用户意图的感知。

Enhanced perception of user intention by combining EEG and gaze-tracking for brain-computer interfaces (BCIs).

机构信息

Division of Electronics and Electrical Engineering, Dongguk University, 26 Pil-dong 3-ga, Jung-gu, Seoul 100-715, Korea.

出版信息

Sensors (Basel). 2013 Mar 13;13(3):3454-72. doi: 10.3390/s130303454.

DOI:10.3390/s130303454

PMID:23486216

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3658756/

Abstract

Speller UI systems tend to be less accurate because of individual variation and the noise of EEG signals. Therefore, we propose a new method to combine the EEG signals and gaze-tracking. This research is novel in the following four aspects. First, two wearable devices are combined to simultaneously measure both the EEG signal and the gaze position. Second, the speller UI system usually has a 6 × 6 matrix of alphanumeric characters, which has disadvantage in that the number of characters is limited to 36. Thus, a 12 × 12 matrix that includes 144 characters is used. Third, in order to reduce the highlighting time of each of the 12 × 12 rows and columns, only the three rows and three columns (which are determined on the basis of the 3 × 3 area centered on the user's gaze position) are highlighted. Fourth, by analyzing the P300 EEG signal that is obtained only when each of the 3 × 3 rows and columns is highlighted, the accuracy of selecting the correct character is enhanced. The experimental results showed that the accuracy of proposed method was higher than the other methods.

摘要

拼写器用户界面系统的准确性往往较低，因为存在个体差异和 EEG 信号的噪声。因此，我们提出了一种新的方法，将 EEG 信号和眼动追踪相结合。这项研究在以下四个方面具有创新性。首先，将两种可穿戴设备结合起来，同时测量 EEG 信号和注视位置。其次，拼写器用户界面系统通常具有 6×6 个字母数字字符的矩阵，其缺点是字符数量限制为 36。因此，使用了包含 144 个字符的 12×12 矩阵。第三，为了减少每行和每列的高亮显示时间，仅高亮显示基于用户注视位置中心的 3×3 区域的三行和三列。第四，通过分析仅在每行和每列高亮显示时获得的 P300 EEG 信号，增强了选择正确字符的准确性。实验结果表明，所提出方法的准确性高于其他方法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4878/3658756/6702d0606515/sensors-13-03454f1.jpg

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通过将脑电图和眼动追踪相结合来增强脑机接口（BCIs）对用户意图的感知。

Enhanced perception of user intention by combining EEG and gaze-tracking for brain-computer interfaces (BCIs).

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