Nonlinear Mapping from EMG to Prosthesis Closing Velocity Improves Force Control with EMG Biofeedback(Article)
- aUniversity of Novi Sad, Faculty of Technical Sciences, Novi Sad, 21102, Serbia
- bOtto Bock Healthcare Products GmbH, Department of Global Research, Vienna, A-1110, Austria
- cOttobock SE & Company KGaA, Department of Global Research, Duderstadt, 37115, Germany
- dAalborg University, Department of Health Science and Technology, Aalborg, 9220, Denmark
Abstract
When using EMG biofeedback to control the grasping force of a myoelectric prosthesis, subjects need to activate their muscles and maintain the myoelectric signal within an appropriate interval. However, their performance decreases for higher forces, because the myoelectric signal is more variable for stronger contractions. Therefore, the present study proposes to implement EMG biofeedback using nonlinear mapping, in which EMG intervals of increasing size are mapped to equal-sized intervals of the prosthesis velocity. To validate this approach, 20 non-disabled subjects performed force-matching tasks using Michelangelo prosthesis with and without EMG biofeedback with linear and nonlinear mapping. Additionally, four transradial amputees performed a functional task in the same feedback and mapping conditions. The success rate in producing desired force was significantly higher with feedback (65.4±15.9%) compared to no feedback (46.2±14.9%) as well as when using nonlinear (62.4±16.8%) versus linear mapping (49.2±17.2%). Overall, in non-disabled subjects, the highest success rate was obtained when EMG biofeedback was combined with nonlinear mapping (72%), and the opposite for linear mapping with no feedback (39.6%). The same trend was registered also in four amputee subjects. Therefore, EMG biofeedback improved prosthesis force control, especially when combined with nonlinear mapping, which showed to be an effective approach to counteract increasing variability of myoelectric signal for stronger contractions. © 2008-2011 IEEE.
Indexed keywords
| Engineering controlled terms: | Artificial limbsBiofeedbackElectromyographyFeedbackForce controlMapping |
|---|---|
| Engineering uncontrolled terms | Biological control systemsEMG biofeedbackForceGraspingGrasping forceGrasping force controlLinear mappingMyoelectric prosthesisNonlinear mappingsVibration |
| Engineering main heading: | Muscle |
| EMTREE medical terms: | amputeebiofeedbackelectromyographyhumanprosthesis designtouch |
| MeSH: | AmputeesArtificial LimbsBiofeedback, PsychologyElectromyographyHumansProsthesis DesignTouch Perception |
Funding details
| Funding sponsor | Funding number | Acronym |
|---|---|---|
| 01-192/34-1 | ||
| Danmarks Frie Forskningsfond | 8022-00243A | DFF |
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1
This work was supported in part by Otto Bock Healthcare Products GmbH through the research project Clinical relevance of somatosensory feedback in transradial amputees Proof of Concept study under Grant 01-192/34-1, and in part by the Independent Danish Research Foundation (DFF) through the project ROBIN under Grant 8022-00243A. This
- ISSN: 19391412
- Source Type: Journal
- Original language: English
- DOI: 10.1109/TOH.2023.3293545
- PubMed ID: 37436850
- Document Type: Article
- Publisher: Institute of Electrical and Electronics Engineers Inc.
Dosen, S.; Aalborg University, Department of Health Science and Technology, Aalborg, Denmark;
© Copyright 2023 Elsevier B.V., All rights reserved.
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