Design, control, and sensory feedback of externally powered hand prostheses: A literature review

Critical Reviews in Biomedical Engineering

Volumn 41, Issue 2, 2013, Pages 161-181

  Cloutier, Aimee ^a   Yang, James ^a  

^a Texas Tech University   (United States)

Author keywords

Control; Design; Hand prosthesis; Sensory feedback

Indexed keywords

CENTRAL NERVOUS SYSTEMS; ELECTROMYOGRAPHIC SIGNAL; HAND PROSTHESIS; MUSCLE CONTRACTIONS; PERIPHERAL NERVOUS SYSTEM; SIGNAL CLASSIFICATION; UNDER-ACTUATED MECHANISM; UPPER LIMB AMPUTATION;

CONTROL; DEGREES OF FREEDOM (MECHANICS); DESIGN; SENSORY FEEDBACK;

PROSTHETICS;

ALLOY;

ARM AMPUTATION; ARTICLE; BAYESIAN LEARNING; CENTRAL NERVOUS SYSTEM; COMPLIANCE (PHYSICAL); CONTROL STRATEGY; CONTROL SYSTEM; ELECTRIC HAND; ELECTROMYOGRAM; ELECTROMYOGRAPHY; ELECTRONEUROGRAPHY; EQUIPMENT DESIGN; EXTERNALLY POWERED HAND PROSTHESIS; FUZZY SYSTEM; GENERAL DEVICE; HAND GRIP; HUMAN; MUSCLE CONTRACTION; MUSCLE REINNERVATION; MYOELECTRICALLY CONTROLLED PROSTHESIS; NERVE CELL NETWORK; PATTERN RECOGNITION; PERIPHERAL NERVOUS SYSTEM; PRIORITY JOURNAL; SENSORY FEEDBACK; SHAPE MEMORY ALLOY ACTUATOR; SIGNAL PROCESSING; VIBROTACTILE MASKING;

AMPUTEES; ARTIFICIAL LIMBS; ELECTROMYOGRAPHY; FEEDBACK, SENSORY; HAND; HUMANS; PROSTHESIS DESIGN;

EID: 84890874755     PISSN: 0278940X     EISSN: None     Source Type: Journal    
DOI: 10.1615/CritRevBiomedEng.2013007887     Document Type: Article

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