Human-machine interfaces based on EMG and EEG applied to robotic systems

Andre Ferreira¹ , Wanderley C Celeste¹ , Fernando A Cheein² , Teodiano F Bastos-Filho¹ , Mario Sarcinelli-Filho¹ and Ricardo Carelli²

¹Department of Electrical Engineering, Federal University of Espirito Santo, Av. Fernando Ferrari, 514, 29075-910, Vitoria-ES, Brazil

²Institute of Automatics, National University of San Juan, Av. San Martin, 1109-Oeste, 5400, San Juan, Argentina

author email corresponding author email

Journal of NeuroEngineering and Rehabilitation 2008, 5:10doi:10.1186/1743-0003-5-10


Published:	26 March 2008

Abstract

Background

Two different Human-Machine Interfaces (HMIs) were developed, both based on electro-biological signals. One is based on the EMG signal and the other is based on the EEG signal. Two major features of such interfaces are their relatively simple data acquisition and processing systems, which need just a few hardware and software resources, so that they are, computationally and financially speaking, low cost solutions. Both interfaces were applied to robotic systems, and their performances are analyzed here. The EMG-based HMI was tested in a mobile robot, while the EEG-based HMI was tested in a mobile robot and a robotic manipulator as well.

Results

Experiments using the EMG-based HMI were carried out by eight individuals, who were asked to accomplish ten eye blinks with each eye, in order to test the eye blink detection algorithm. An average rightness rate of about 95% reached by individuals with the ability to blink both eyes allowed to conclude that the system could be used to command devices. Experiments with EEG consisted of inviting 25 people (some of them had suffered cases of meningitis and epilepsy) to test the system. All of them managed to deal with the HMI in only one training session. Most of them learnt how to use such HMI in less than 15 minutes. The minimum and maximum training times observed were 3 and 50 minutes, respectively.

Conclusion

Such works are the initial parts of a system to help people with neuromotor diseases, including those with severe dysfunctions. The next steps are to convert a commercial wheelchair in an autonomous mobile vehicle; to implement the HMI onboard the autonomous wheelchair thus obtained to assist people with motor diseases, and to explore the potentiality of EEG signals, making the EEG-based HMI more robust and faster, aiming at using it to help individuals with severe motor dysfunctions.