Proportional myoelectric and compensating control of a cable-conduit mechanism-driven upper limb exoskeleton

Recent studies have indicated that human motion recognition based on surface electromyography (sEMG) is a reliable and natural method for achieving motion intention. However, achieving accurate estimates of intended motion using a low computational cost is the main challenge in this scenario. In thi...

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Bibliographic Details
Published in:ISA transactions 2019-06, Vol.89, p.245-255
Main Author: Xiao, Feiyun
Format: Article
Language:English
Subjects:
Adult
Algorithms
Biomechanical Phenomena
Cable-conduit
Electromyography - methods
Electronics
Exoskeleton
Exoskeleton Device
Female
Healthy Volunteers
Humans
Integral signal
Male
Movement - physiology
Reproducibility of Results
sEMG
Support Vector Machine
SVM
Time-delayed
Upper Extremity
Young Adult
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Summary:Recent studies have indicated that human motion recognition based on surface electromyography (sEMG) is a reliable and natural method for achieving motion intention. However, achieving accurate estimates of intended motion using a low computational cost is the main challenge in this scenario. In this study, a proportional myoelectric and compensating control method for estimating and assisting human motion intention with a cable-conduit mechanism-driven upper limb exoskeleton was proposed. The integral signal of sEMG and its time-delayed signals were applied as a new feature vector to represent the role of sEMG, which ensured the accuracy and real-time performance of motion estimation. An integrated circuit was used to reduce time of feature extraction. A feed-forward compensator was designed to compensate for the effect of the hysteresis problem in the exoskeleton, which is inevitable when the cable-conduit mechanism was applied to reduce the exoskeleton weight. The model-free control method based on PID method and least squares support vector machine were applied to avoid calculating the complex biomechanical model of human upper limb and the dynamic model of exoskeleton. Experimental results validated the proposed method. The average values of the root-mean-square difference (RMSD) for motion estimation were 0.0579 ± 0.0085 [motion with constant pace (CP)] and 0.0845 ± 0.0137 [motion with variable pace (VP)]. The Bland–Altman analysis results showed that the estimated angle of the proposed method was consistent with the actual angle. The performance of the control method was good, and the accuracies were 98.5608% ± 0.4485% (motion with CP) and 96.6119% ± 0.6628% (motion with VP). •A proportional myoelectric compensating control method of exoskeleton is proposed.•The integral signal of sEMG and its time-delayed signals are used as a new feature vector.•The course of feature extraction is realized by the integrated circuit.•It does not require to calculate the complex bio-mechanical model of human upper limb.
ISSN:0019-0578
1879-2022
DOI:10.1016/j.isatra.2018.12.028