Limb Position Tolerant Pattern Recognition for Myoelectric Prosthesis Control with Adaptive Sparse Representations From Extreme Learning

• Published in: IEEE transactions on biomedical engineering Vol. 65; no. 4; pp. 770 - 778
• Main Authors: Betthauser, Joseph L., Hunt, Christopher L., Osborn, Luke E., Masters, Matthew R., Levay, Gyorgy, Kaliki, Rahul R., Thakor, Nitish V.
• Format: Journal Article
• Language: English
• Published: United States IEEE 01.04.2018; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Abandonment; Adaptive control; Aged; Amputation; Amputee; Amputees - rehabilitation; Artificial Limbs; Classification; EASRC; Electromyography; Electromyography - methods; EMG; Female; Humans; limb position; Machine Learning; Male; Middle Aged; myoelectric; Myoelectricity; Pattern recognition; Pattern Recognition, Automated - methods; Posture - physiology; Prostheses; prosthesis; Prosthetics; Real-time systems; robust; Robustness; Signal Processing, Computer-Assisted; sparse; SRC; Training; Training data; User-Computer Interface
• ISSN: 0018-9294; 1558-2531; 1558-2531
• DOI: 10.1109/TBME.2017.2719400

Myoelectric signals can be used to predict the intended movements of an amputee for prosthesis control. However, untrained effects like limb position changes influence myoelectric signal characteristics, hindering the ability of pattern recognition algorithms to discriminate among motion classes. Despite frequent and long training sessions, these deleterious conditional influences may result in poor performance and device abandonment. Goal: We present a robust sparsity-based adaptive classification method that is significantly less sensitive to signal deviations resulting from untrained conditions. Methods: We compare this approach in the offline and online contexts of untrained upper-limb positions for amputee and able-bodied subjects to demonstrate its robustness compared against other myoelectric classification methods. Results: We report significant performance improvements (p<;0.001) in untrained limb positions across all subject groups. Significance: The robustness of our suggested approach helps to ensure better untrained condition performance from fewer training conditions. Conclusions: This method of prosthesis control has the potential to deliver real-world clinical benefits to amputees: better condition-tolerant performance, reduced training burden in terms of frequency and duration, and increased adoption of myoelectric prostheses.