• DocumentCode
    1763001
  • Title

    Intuitive, Online, Simultaneous, and Proportional Myoelectric Control Over Two Degrees-of-Freedom in Upper Limb Amputees

  • Author

    Ning Jiang ; Rehbaum, H. ; Vujaklija, Ivan ; Graimann, Bernhard ; Farina, Dario

  • Author_Institution
    Dept. of Neurorehabilitation Eng., Univ. Med. Center Gottingen, Gottingen, Germany
  • Volume
    22
  • Issue
    3
  • fYear
    2014
  • fDate
    41760
  • Firstpage
    501
  • Lastpage
    510
  • Abstract
    We propose an approach for online simultaneous and proportional myoelectric control of two degrees-of-freedom (DoF) of the wrist, using surface electromyographic signals. The method is based on the nonnegative matrix factorization (NMF) of the wrist muscle activation to extract low-dimensional control signals translated by the user into kinematic variables. This procedure does not need a training set of signals for which the kinematics is known (labeled dataset) and is thus unsupervised (although it requires an initial calibration without labeled signals). The estimated control signals using NMF are used to directly control two DoFs of wrist. The method was tested on seven subjects with upper limb deficiency and on seven able-bodied subjects. The subjects performed online control of a virtual object with two DoFs to achieve goal-oriented tasks. The performance of the two subject groups, measured as the task completion rate, task completion time, and execution efficiency, was not statistically different. The approach was compared, and demonstrated to be superior to the online control by the industrial state-of-the-art approach. These results show that this new approach, which has several advantages over the previous myoelectric prosthetic control systems, has the potential of providing intuitive and dexterous control of artificial limbs for amputees.
  • Keywords
    artificial limbs; biomechanics; calibration; electromyography; feature extraction; information services; kinematics; matrix decomposition; medical control systems; medical signal processing; statistical analysis; virtual reality; NMF; calibration; dexterous artificial limb control; execution efficiency; goal-oriented tasks; industrial state-of-the-art approach; intuitive artificial limb control; intuitive myoelectric control; kinematic variables; low-dimensional control signal extraction; low-dimensional control signal translation; myoelectric prosthetic control systems; nonnegative matrix factorization; online simultaneous myoelectric control; online virtual object control; proportional myoelectric control; statistical analysis; surface electromyographic signals; task completion rate; task completion time; two degrees-of-freedom myoelectric control; upper limb amputees; upper limb deficiency; wrist muscle activation; Calibration; Electromyography; Kinematics; Muscles; Prosthetics; Semiconductor optical amplifiers; Wrist; Muscle synergy; myoelectric signal processing; non-negative matrix factorization; prosthetic control;
  • fLanguage
    English
  • Journal_Title
    Neural Systems and Rehabilitation Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1534-4320
  • Type

    jour

  • DOI
    10.1109/TNSRE.2013.2278411
  • Filename
    6587087