• DocumentCode
    1207763
  • Title

    Estimation of the 3-D center of mass excursion from force-plate data during standing

  • Author

    Barbier, Franck ; Allard, Paul ; Guelton, Kevin ; Colobert, Briac ; Godillon-Maquinghen, Anne-Pascale

  • Author_Institution
    Lab. d´´Automatique et de Mecanique Industrielles et Humaines, Univ. de Valenciennes, France
  • Volume
    11
  • Issue
    1
  • fYear
    2003
  • fDate
    3/1/2003 12:00:00 AM
  • Firstpage
    31
  • Lastpage
    37
  • Abstract
    Biomechanical models are used with force-plate information to determine the center of mass (COM) trajectory during standing. They are usually based on simplifying assumptions and are often limited to a single-plane analysis. The objectives of this study were to present a three-dimensional (3-D) model to calculate the excursion of the COM of the human body, validate it and compare its performance to a video-based system during quiet standing and antero-posterior (AP) and medio-lateral (ML) self-imposed oscillations. In addition to the vertical displacements of the COM, the originality of the method lies in eliminating the accelerations terms in the model and their related assumptions. The model was able to estimate closely the COM displacements in quiet standing [a root mean square (RMS) of 0.9 mm or less]. For the self-imposed oscillations, the RMS differences were 6.6 mm in the AP and ML directions and 1.6 mm along the vertical axis. For all three testing conditions, the coefficients of correlation of the COM displacements between the model and the video methods were above 0.8 with the exception of the vertical direction, where the values were more variable.
  • Keywords
    biomechanics; oscillations; physiological models; 3-D center of mass excursion; accelerations terms elimination; force-plate data; human body; medio-lateral self-imposed oscillations; quiet standing; simplifying assumptions; single-plane analysis; vertical axis; vertical direction; vertical displacements; video methods; Acceleration; Biological system modeling; Educational institutions; Helium; Humans; Monitoring; Neuromuscular; Pathology; Root mean square; Testing; Acceleration; Adult; Computer Simulation; Feasibility Studies; Foot; Humans; Male; Models, Biological; Movement; Muscle, Skeletal; Musculoskeletal Equilibrium; Posture; Pressure; Reproducibility of Results; Sensitivity and Specificity; Stress, Mechanical; Torque;
  • fLanguage
    English
  • Journal_Title
    Neural Systems and Rehabilitation Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1534-4320
  • Type

    jour

  • DOI
    10.1109/TNSRE.2003.810433
  • Filename
    1200904