A novel approach for communicating with patients suffering from completely locked-in-syndrome (CLIS) via thoughts: Brain computer interface system using EEG signals and artificial intelligence
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引用次数: 1
Abstract
This paper investigates the development of an intelligent system method to address completely locked-in-syndrome (CLIS) that is caused by some illnesses such as Amyotrophic Lateral Sclerosis (ALS) as the most predominant type of Motor Neuron Disease (MND). In the last stages of ALS and despite the limitations in body movements, patients however will have a fully functional brain and cognitive capabilities and able to feel pain but fail to communicate. This paper aims to address the CLIS problem by utilizing EEG signals that human brain generates when thinking about a specific feeling or imagination as a way to communicate. The aim is to develop a low-cost and affordable system for patients to use to communicate with carers and family members. In this paper, the novel implementation of the ASPS (Automated Sensor and Signal Processing Selection) approach for feature extraction of EEG is presented to select the most suitable Sensory Characteristic Features (SCFs) to detect human thoughts and imaginations. Artificial Neural Networks (ANN) are used to verify the results. The findings show that EEG signals are able to capture imagination information that can be used as a means of communication; and the ASPS approach allows the selection of the most important features for reliable communication. This paper explains the implementation and validation of ASPS approach in brain signal classification for bespoke arrangement. Hence, future work will present the results of relatively high number of volunteers, sensors and signal processing methods.
本文研究了一种智能系统方法的发展,以解决由一些疾病引起的完全闭锁综合征(CLIS),如肌萎缩侧索硬化症(ALS)是运动神经元疾病(MND)的最主要类型。在肌萎缩侧索硬化症的最后阶段,尽管身体活动受到限制,但患者的大脑功能和认知能力将完全正常,能够感受到疼痛,但无法沟通。本文旨在利用人类大脑在思考特定感觉或想象时产生的脑电图信号作为一种交流方式来解决CLIS问题。其目的是开发一种低成本和负担得起的系统,供患者用于与护理人员和家庭成员沟通。本文提出了一种新的EEG特征提取方法——自动传感器和信号处理选择(Automated Sensor and Signal Processing Selection, ASPS),以选择最合适的感官特征(Sensory Characteristic Features, SCFs)来检测人的思想和想象。使用人工神经网络(ANN)对结果进行验证。研究结果表明,脑电图信号能够捕获想象信息,可以用作一种交流手段;而asp方法允许选择最重要的特性来实现可靠的通信。本文阐述了在定制排序的脑信号分类中应用ASPS方法的实现和验证。因此,未来的工作将呈现相对较多的志愿者,传感器和信号处理方法的结果。
Neuroscience informaticsSurgery, Radiology and Imaging, Information Systems, Neurology, Artificial Intelligence, Computer Science Applications, Signal Processing, Critical Care and Intensive Care Medicine, Health Informatics, Clinical Neurology, Pathology and Medical Technology