Application Specific Reconfigurable Processor for Eyeblink Detection from Dual-Channel EOG Signal

IF 1.6 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Journal of Low Power Electronics and Applications Pub Date : 2023-11-23 DOI:10.3390/jlpea13040061
Diba Das, M. Chowdhury, Aditta Chowdhury, Kamrul Hasan, Q. D. Hossain, Ray C. C. Cheung
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Abstract

The electrooculogram (EOG) is one of the most significant signals carrying eye movement information, such as blinks and saccades. There are many human–computer interface (HCI) applications based on eye blinks. For example, the detection of eye blinks can be useful for paralyzed people in controlling wheelchairs. Eye blink features from EOG signals can be useful in drowsiness detection. In some applications of electroencephalograms (EEGs), eye blinks are considered noise. The accurate detection of eye blinks can help achieve denoised EEG signals. In this paper, we aimed to design an application-specific reconfigurable binary EOG signal processor to classify blinks and saccades. This work used dual-channel EOG signals containing horizontal and vertical EOG signals. At first, the EOG signals were preprocessed, and then, by extracting only two features, the root mean square (RMS) and standard deviation (STD), blink and saccades were classified. In the classification stage, 97.5% accuracy was obtained using a support vector machine (SVM) at the simulation level. Further, we implemented the system on Xilinx Zynq-7000 FPGAs by hardware/software co-design. The processing was entirely carried out using a hybrid serial–parallel technique for low-power hardware optimization. The overall hardware accuracy for detecting blinks was 95%. The on-chip power consumption for this design was 0.8 watts, whereas the dynamic power was 0.684 watts (86%), and the static power was 0.116 watts (14%).
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针对特定应用的可重构处理器,用于从双通道眼动图信号中检测眼球信号
眼电图(EOG)是携带眼球运动信息(如眨眼和眼球移动)的最重要信号之一。基于眨眼的人机交互(HCI)应用很多。例如,眨眼检测可以帮助瘫痪者控制轮椅。脑电信号中的眨眼特征可用于嗜睡检测。在脑电图(EEG)的某些应用中,眨眼被视为噪声。准确检测眨眼有助于实现去噪 EEG 信号。本文旨在设计一种针对特定应用的可重构二进制 EOG 信号处理器,对眨眼和眼球移动进行分类。这项工作使用了包含水平和垂直 EOG 信号的双通道 EOG 信号。首先对眼动图信号进行预处理,然后仅通过提取均方根(RMS)和标准偏差(STD)这两个特征对眨眼和眼球移动进行分类。在分类阶段,使用支持向量机(SVM)在模拟水平上获得了 97.5% 的准确率。此外,我们还通过硬件/软件协同设计在 Xilinx Zynq-7000 FPGA 上实现了该系统。处理过程完全采用串行-并行混合技术,以实现低功耗硬件优化。检测闪烁的总体硬件准确率为 95%。该设计的片上功耗为 0.8 瓦,动态功耗为 0.684 瓦(86%),静态功耗为 0.116 瓦(14%)。
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来源期刊
Journal of Low Power Electronics and Applications
Journal of Low Power Electronics and Applications Engineering-Electrical and Electronic Engineering
CiteScore
3.60
自引率
14.30%
发文量
57
审稿时长
11 weeks
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