Notes on the margin of stability

Notes on the margin of stability

The concept of the 'extrapolated center of mass (XcoM)', introduced by Hof et al., (2005, J. Biomechanics 38 (1), p. 1–8), extends the classical inverted pendulum model to dynamic situations. The vector quantity XcoM combines the center of mass position plus its velocity divided by the pen...

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Veröffentlicht in:Journal of biomechanics 2024-03, Vol.166, p.112045-112045, Article 112045
Hauptverfasser: Curtze, Carolin, Buurke, Tom J.W., McCrum, Christopher
Format: Artikel
Sprache:eng
Schlagworte:
Biomechanics
Center of mass
Dynamic balance
Dynamic stability
Extrapolated center of mass
Gait stability
Locomotion
Pendulums
Resonant frequencies
Velocity
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Zusammenfassung:The concept of the 'extrapolated center of mass (XcoM)', introduced by Hof et al., (2005, J. Biomechanics 38 (1), p. 1–8), extends the classical inverted pendulum model to dynamic situations. The vector quantity XcoM combines the center of mass position plus its velocity divided by the pendulum eigenfrequency. In this concept, the margin of stability (MoS), i.e., the minimum signed distance from the XcoM to the boundaries of the base of support was proposed as a measure of dynamic stability. Here we describe the conceptual evolution of the XcoM, discuss key considerations in the estimation of the XcoM and MoS, and provide a critical perspective on the interpretation of the MoS as a measure of instantaneous mechanical stability.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2024.112045