Design of Portable Wireless Intelligent Interactive System Based on Eye Movement Signal
Gao Dongrui1,2#, Wang Rungui2, Ying Shaofei2, Jiang Dong2, Chen Jiaxin2, Zong Xin2, Dong Lijuan2, Song Xiaoyu2, Wang Lutao1*
1(School of Computer Science, Chengdu University of Information Technology, Chengdu 610225, China) 2(Center for Information in Medicine, University of Electronic Science and Technology of China, Chengdu 610054, China)
Abstract:Patients with motor impairment are unable to control modern electronic devices (mobile phones, iPAD, etc.) to communicate with the outside world. It is difficult for them to integrate into information-based society. In this paper, a portable wireless intelligent interactive system was designed to help users control electronic devices with their own eye movement signals to help them communicate with the outside world. The system was made up of analog and digital circuits. The analog circuit was used for filtering and amplification. The digital circuit was used to convert analog signals to digital signals, and then the digital signals were analyzed and processed in real time. It included using short-term energy endpoints to obtain starting and ending positions of signal activity segments, selecting location, amplitude, and wave peak number as signal characteristics, and then using zero-crossing analysis and dynamic threshold method to identify different types of eye movement signals. At last a state machine was used to define the corresponding relationship between different types of eye signals and mouse movements in the electronic devices. Fifteen subjects were enrolled for the test, they were required to control five different eye movements according to random instructions, including looking up, down, left, right and active blinking, and each action was performed 100 times in total. Results showed that the average accuracy of each eye movement was more than 94%, and the minimum average information transfer rate was more than 22 bits/min. In conclusion, this system could use the eye movement to replace the mouse to control electronic devices, realizing functions of character input, making phone calls, listening to music, and browsing the web.
[1] Yunjun N, Bonkon K, Andrzej C, et al. GOM-Face: GKP, EOG, and EMG-based multimodal interface with application to humanoid robot control[J]. IEEE Transactions on Biomedical Engineering, 2014, 61(2):453-462. [2] 丁其川, 熊安斌, 赵新刚, et al. 基于表面肌电的运动意图识别方法研究及应用综述[J]. 自动化学报, 2016, 42(1):13-25. [3] Mcfarland DJ, Mccane LM, David SV, et al. Spatial filter selection for EEG-based communication[J]. Electroencephalography & Clinical Neurophysiology, 1997, 103(3):386-394. [4] Pfurtscheller G, Flotzinger D, Kalcher J. Brain-computer interface—A new communication device for handicapped persons[J]. Journal of Microcomputer Applications, 1993, 16(3):293-299. [5] Duncan JC, Donchin E. On quantifying surprise: the variation of event-related potentials with subjective probability[J]. Psychophysiology, 2010, 14(5):456-467. [6] Panicker RC, Puthusserypady S, Sun Y. An Asynchronous P300 BCI with SSVEP-based control state detection[J]. IEEE Transactions on Biomedical Engineering, 2011, 58(6):1781-1788. [7] DaCruz JN, Wan F, Wong CM, et al. Adaptive time-window length based on online performance measurement in SSVEP-based BCIs[J]. Neurocomputing, 2015, 149(1):93-99. [8] Farwell LA, Donchin E. Talking off the top of your head: toward a mental prosthesis utilizing event-related brain potentials[J]. Electroencephalography and Clinical Neurophysiology, 1989, 70(6):510-523. [9] Yu T, Li Y, Long J, et al. Surfing the internet with a BCI mouse[J]. Journal of Neural Engineering, 2012, 9(3):036012. [10] Yangsong Z, Peng X, Tiejun L, et al. Multiple frequencies sequential coding for SSVEP-Based brain-computer interface[J]. PLoS one, 2012, 7(3):e29519. [11] Lin K, Wang Y, Gao X. Time-frequency joint coding method for boosting information transfer rate in an SSVEP based BCI system[C]// 38th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. Florida: IEEE, 2016:5873-5876. [12] Kamel N, Aamir SM. EEG/ERP Analysis: Methods and Applications[M]. 2th Edition, Canada: Apple Academic Press Inc, 2014: 20-25. [13] Saponas TS, Tan DS, Dan M, et al. Making Muscle-Computer Interfaces More Practical[C]// Proceedings of the 28th International Conference on Human Factors in Computing Systems. Atlanta:CHI, 2010:851-855. [14] Fleischer C, Hommel G. A Human--exoskeleton interface utilizing electromyography[J]. IEEE Transactions on Robotics, 2008, 24(4):872-882. [15] 张洁,崔丽英. 肌萎缩侧索硬化患者的重复神经电刺激特点[J]. 中国神经免疫学和神经病学杂志, 2016, 23(1):25-28. [16] 李勃. 脑机接口技术研究综述[J]. 数字通信, 2013, 40(4):5-8. [17] 张丹, 李佳蔚. 探索思维的力量探索思维的力量:脑机接口研究现状与展望[J]. 科技导报, 2017, 35(9):62-67. [18] Hochberg LR, Bacher D, Jarosiewicz B, et al. Reach and grasp by people with tetraplegia using a neurally controlled robotic arm[J]. Nature, 2013, 485(7398):372-375. [19] 郜东瑞, 甘玉龙, 李鹏霄, 等. 基于眼电的智能输入系统研究[J]. 中国生物医学工程学报, 2015, 34(6):662-669. [20] Ghaheri H, Ahmadyfard A. Extracting common spatial patterns from EEG time segments for classifying motor imagery classes in a Brain Computer Interface (BCI) [J]. Scientia Iranica, 2013, 20(6):2061-2072. [21] 张焕, 乔晓艳. 多任务运动想象脑电特征的融合分类研究[J]. 传感技术学报, 2016, 29(6):802-807. [22] 欧祖宏. 林铭铎. 基于SSVEP与运动想象的实时脑控阿凡达系统[J].计算机与现代化, 2018, 269(1):36-39. [23] Pandarinath C, Nuyujukian P, Blabe CH, et al. High performance communication by people with paralysis using an intracortical brain-computer interface[J]. Human Biology and Medicine, 2017, 6(1):e18554.
