A neuromusculoskeletal model of the human upper limb for a myoelectric exoskeleton control using a reduced number of muscles

Author

Buongiorno, Domenico ; Barsotti, Michele ; Sotgiu, Edoardo ; Loconsole, Claudio ; Solazzi, Massimiliano ; Bevilacqua, Vitoantonio ; Frisoli, Antonio

Author_Institution

PERCRO Lab., TeCIP Inst., Pisa, Italy

fYear

2015

fDate

22-26 June 2015

Firstpage

273

Lastpage

279

Abstract

This paper presents a myoelectric control of an arm exoskeleton designed for rehabilitation. A four-muscles-based NeuroMusculoSkeletal (NMS) model was implemented and optimized using genetic algorithms to adapt the model to different subjects. The NMS model is able to predict the shoulder and elbow torques which are used by the control algorithm to ensure a minimal force of interaction. The accuracy of the method is assessed through validation experiments conducted with two healthy subjects performing free movements along the pseudo-sagittal plane. The experiments show promising results for our approach showing its potential for being introduced in a rehabilitation protocol.

Keywords

electromyography; genetic algorithms; medical control systems; medical signal processing; patient rehabilitation; NMS model; arm exoskeleton; control algorithm; elbow torque; free movement; genetic algorithm; human upper limb; interaction force; myoelectric exoskeleton control; neuromusculoskeletal model; pseudosagittal plane; rehabilitation protocol; shoulder torque; Elbow; Force; Joints; Muscles; Optimization; Shoulder; Torque; Exoskeleton; Genetic Algorithm; Myoelectric Control; NeuroMusculoSkeletal Model; Upper Limb; sEMG signals;

fLanguage

English

Publisher

ieee

Conference_Titel

World Haptics Conference (WHC), 2015 IEEE

Conference_Location

Evanston, IL

Type

conf

DOI

10.1109/WHC.2015.7177725

Filename

7177725