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Control of a robotic knee exoskeleton for assistance and rehabilitation based on motion intention from sEMG
Villa-Parra, Ana Cecilia; Delisle-Rodriguez, Denis; Botelho, Thomaz; Mayor, John Jairo Villarejo; Delis, Alberto López; Carelli, Ricardo; Frizera Neto, Anselmo; Bastos, Teodiano Freire.
Afiliação
  • Villa-Parra, Ana Cecilia; Federal University of Espirito Santo. Postgraduate Program in Electrical Engineering. Vitoria. BR
  • Delisle-Rodriguez, Denis; Federal University of Espirito Santo. Postgraduate Program in Electrical Engineering. Vitoria. BR
  • Botelho, Thomaz; Federal University of Espirito Santo. Postgraduate Program in Electrical Engineering. Vitoria. BR
  • Mayor, John Jairo Villarejo; Federal University of Parana. Postgraduate Program in Physical Education. Curitiba. BR
  • Delis, Alberto López; University of Oriente. Center of Medical Biophysics. Santiago de Cuba. CU
  • Carelli, Ricardo; National University of San Juan. Institute of Automatics. San Juan. AR
  • Frizera Neto, Anselmo; Federal University of Espirito Santo. Postgraduate Program in Electrical Engineering. Vitoria. BR
  • Bastos, Teodiano Freire; Federal University of Espirito Santo. Postgraduate Program in Electrical Engineering. Vitoria. BR
Res. Biomed. Eng. (Online) ; 34(3): 198-210, July.-Sept. 2018. tab, graf
Article em En | LILACS | ID: biblio-984953
Biblioteca responsável: BR1.1
ABSTRACT

Introduction:

This work presents the development of a novel robotic knee exoskeleton controlled by motion intention based on sEMG, which uses admittance control to assist people with reduced mobility and improve their locomotion. Clinical research remark that these devices working in constant interaction with the neuromuscular and skeletal human system improves functional compensation and rehabilitation. Hence, the users become an active part of the training/rehabilitation, facilitating their involvement and improving their neural plasticity. For recognition of the lower-limb motion intention and discrimination of knee movements, sEMG from both lower-limb and trunk are used, which implies a new approach to control robotic assistive devices. Methods A control system that includes a stage for human-motion intention recognition (HMIR), based on techniques to classify motion classes related to knee joint were developed. For translation of the user's intention to a desired state for the robotic knee exoskeleton, the system also includes a finite state machine and admittance, velocity and trajectory controllers with a function that allows stopping the movement according to the users intention. Results The proposed HMIR showed an accuracy between 76% to 83% for lower-limb muscles, and 71% to 77% for trunk muscles to classify motor classes of lower-limb movements. Experimental results of the controller showed that the admittance controller proposed here offers knee support in 50% of the gait cycle and assists correctly the motion classes. Conclusion The robotic knee exoskeleton introduced here is an alternative method to empower knee movements using sEMG signals from lower-limb and trunk muscles.
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Texto completo: 1 Coleções: 01-internacional Base de dados: LILACS Idioma: En Revista: Res. Biomed. Eng. (Online) Assunto da revista: Engenharia Biom‚dica Ano de publicação: 2018 Tipo de documento: Article País de afiliação: Argentina / Brasil / Cuba País de publicação: Brasil

Texto completo: 1 Coleções: 01-internacional Base de dados: LILACS Idioma: En Revista: Res. Biomed. Eng. (Online) Assunto da revista: Engenharia Biom‚dica Ano de publicação: 2018 Tipo de documento: Article País de afiliação: Argentina / Brasil / Cuba País de publicação: Brasil