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Abstract

This paper describes a technique for the calculation of a lumped-mass representation of a human based on acceleration of body locations, typically obtained from a three-dimensional motion tracking system, and external forces and torques, typically measured from a force plate. The inverse problem of solving for lumped masses is presented, which results in a mass model of the individual subject via a fast, fully automated approach. This method can be used to obtain the mass model per se for the identification of growth deformities or together with a kinematic model for inverse and forward dynamics. Furthermore the mass model and acceleration trajectories subsequently can be used to calculate the contact forces between the floor and the subject at locations remote to a force plate.

Keywords

human lumped-mass model acceleration force plate

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References

Winter

D. A.

Biomechanics and Motor Control of Human Movement, 2nd edition, 1990, pp. 75–102 (John Wiley, New York).

Spagele

Kistner

Gollhofer

Modelling, simulation and optimisation of a human vertical jump. J. Biomechanics, 1999, 32, 521–530.

Hungerford

D. S.

Barry

Biomechanics of the patellofemoral joint. Clin. Orthop., 1979, 144, 9–15.

Bell

A. L.

Petersen

D. R.

Brand

R. A.

Prediction of hip joint center location from external markers. Human Movement Sci., 1989, 8, 3–16.

Bell

A. L.

Petersen

D. R.

Brand

R. A.

A comparison of the accuracy of several hip center location predicition methods. J. Biomechanics, 1990, 23, 617–621.

Cappozzo

Gait analysis methodology. Human Movement Sci., 1984, 3, 27–54.

Dempster

Space requirements of the seated operator. WADC Technical Report 55–159, Office of Technical Services, US Department of Commerce, 1955.

Jensen

R. K.

Estimation of the biomechanical properties of three body types using a photogrammetric method. J. Biomechanics., 1978, 13, 349–358.

Jensen

R. K.

The effect of a 12-month growth period on the body moments of inertia of children. Med. Sci. Sports Exercise, 1981, 13, 238–242.

10.

Miller

D. I.

Morrison

W. E.

Prediction of segmental parameters using the Hanavan human body model. Med. Sci. Sport, 1975, 7, 207–212.

11.

Baumann

J. U.

Schaer

D. B.

Sheffer

D. B.

Evaluation of human segmental body volume and inertial properties with photogrammetry as a basis for gait analysis. Biostereometrics, 1995, 85, 156–159.

12.

Jurčević

Muftic

Determination of central dynamic moments of inertia of body segments. Coll. Antropol., 1998, 22, 585–592.

13.

Hatze

A mathematical model for the computational determination of parameter values of anthropomorphic segments. J. Biomechanics, 1980, 13, 833–843.