Characterized Bioelectric Signals by Means of Neural Networks and Wavelets to Remotely Control a Human-Machine Interface

Everyday, people interact with different types of human machine interfaces, and the use of them is increasing, thus, it is necessary to design interfaces which are capable of responding in an intelligent, natural, inexpensive, and accessible way, regardless of social, cultural, economic, or physical...

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Published in:Sensors (Basel, Switzerland) Switzerland), 2019-04, Vol.19 (8), p.1923
Main Authors: Tinoco Varela, David, Gudiño Peñaloza, Fernando, Villaseñor Rodelas, Carolina Jeanette
Format: Article
Language:English
Subjects:
Algorithms
biosignals
command and control systems
human machine interfaces
Humans
integrated circuit interconnections
intelligent control
Man-Machine Systems
nano systems
Neural Networks (Computer)
User-Computer Interface
wavelets
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creator Tinoco Varela, David
Gudiño Peñaloza, Fernando
Villaseñor Rodelas, Carolina Jeanette
description Everyday, people interact with different types of human machine interfaces, and the use of them is increasing, thus, it is necessary to design interfaces which are capable of responding in an intelligent, natural, inexpensive, and accessible way, regardless of social, cultural, economic, or physical features of a user. In this sense, it has been sought out the development of small interfaces to avoid any type of user annoyance. In this paper, bioelectric signals have been analyzed and characterized in order to propose a more natural human-machine interaction system. The proposed scheme is controlled by electromyographic signals that a person can create through arm movements. Such arm signals have been analyzed and characterized by a back-propagation neural network, and by a wavelet analysis, in this way control commands were obtained from such arm electromyographic signals. The developed interface, uses Extensible Messaging and Presence Protocol (XMPP) to send control commands remotely. In the experiment, it manipulated a vehicle that was approximately 52 km away from the user, with which it can be showed that a characterized electromyographic signal can be sufficient for controlling embedded devices such as a Raspberri Pi, and in this way we can use the neural network and the wavelet analysis to generate control words which can be used inside the Internet of Things too. A Tiva-C board has been used to acquire data instead of more popular development boards, with an adequate response. One of the most important aspects related to the proposed interface is that it can be used by almost anyone, including people with different abilities and even illiterate people. Due to the existence of individual efforts to characterize different types of bioelectric signals, we propose the generation of free access Bioelectric Control Dictionary, to define and consult each characterized biosignal.
doi_str_mv 10.3390/s19081923
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subjects Algorithms
biosignals
command and control systems
human machine interfaces
Humans
integrated circuit interconnections
intelligent control
Man-Machine Systems
nano systems
Neural Networks (Computer)
User-Computer Interface
wavelets
title Characterized Bioelectric Signals by Means of Neural Networks and Wavelets to Remotely Control a Human-Machine Interface
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