Synchronized Detection of Evoked Potentials to Drive a High Information Transfer Rate Hybrid Brain-Computer Interface Application

IF 0.8 Q4 ENGINEERING, BIOMEDICAL Advanced Biomedical Engineering Pub Date : 2021-01-01 DOI:10.14326/ABE.10.58
Akshay Katyal, R. Singla
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引用次数: 1

Abstract

Brain-computer interfaces (BCIs) recently have been focusing on combining various BCI modalities to form different combinations of hybrid BCIs. These paradigms are designed to elicit more than one brain potential in the form of BCI features. This research is being carried out with the objective of increasing classification accuracy and information transfer rate (ITR) based on measurement of brain potentials. This study proposed a novel hybrid BCI elicitation and measurement technique combining steady-state visually evoked potential (SSVEP) and P300 potentials to increase the ITR. The hybrid BCI also increased the number of target options compared to SSVEP paradigm for a set number of presumed frequencies of flickering. One of the hybrid BCIs used distinct colours along with distinct flickering frequencies for targets, with an aim to increase the accuracy of classification and reduction of system uncertainty parameter known as false activation rate (FAR). The results of a study in 10 volunteers established that the novel SSVEP-P300 hybrid BCI with distinct colours for target frequencies had average parameters as follows: classification accuracy of 90.76%, ITR of 81.10 bits / min and FAR of 2.99%. A comparative study of the two novel paradigms with SSVEP and P300 paradigms in the same environment was conducted. The results of the comparative study concluded that the hybrid BCI with distinct colours for various target frequencies yielded the best results and hence can be considered as a viable paradigm option for the development of an assistive device.
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诱发电位同步检测驱动高信息传输速率混合脑机接口的应用
近年来,脑机接口(BCI)研究的重点是将不同的脑机接口模式结合起来,形成不同的混合脑机接口组合。这些范例旨在以脑机接口特征的形式引出不止一种大脑潜能。本研究的目的是在脑电位测量的基础上提高分类准确率和信息传递率。本研究提出了一种结合稳态视觉诱发电位(SSVEP)和P300电位的新型混合脑机接口激发和测量技术,以提高ITR。与SSVEP模式相比,混合脑机接口在一定数量的假定闪烁频率下也增加了目标选项的数量。其中一种混合脑机接口使用不同的颜色和不同的闪烁频率作为目标,目的是提高分类的准确性和减少系统的不确定性参数,即误激活率(FAR)。对10名志愿者的研究结果表明,新型SSVEP-P300混合脑机接口具有不同颜色的目标频率,其平均参数如下:分类准确率为90.76%,ITR为81.10 bits / min, FAR为2.99%。将两种新范式与SSVEP和P300范式在同一环境下进行比较研究。对比研究的结果表明,不同目标频率的不同颜色的混合脑机接口产生了最好的结果,因此可以被认为是辅助装置开发的可行范例选择。
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来源期刊
Advanced Biomedical Engineering
Advanced Biomedical Engineering ENGINEERING, BIOMEDICAL-
CiteScore
1.40
自引率
10.00%
发文量
15
审稿时长
15 weeks
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