This content is not included in
your SAE MOBILUS subscription, or you are not logged in.
Comparison of Bi-planar Radiography and Adjusted Scaling Equations for the Computation of Appropriate 3D Body Segment Inertial Parameters
Technical Paper
2006-01-2372
ISSN: 0148-7191, e-ISSN: 2688-3627
Annotation ability available
Sector:
Language:
English
Abstract
The Body Segments Inertial Parameters (BSIPs) are essential data in biomechanics. However, the measurements on cadaver are restrictive and the measurements on living human remain limiting. Moreover, in the literature, the predictive equations are mainly 2D and include two restraining assumptions. Accordingly, it is still challenging to obtain appropriate 3D BSIPs. A bi-planar radiographic method, previously developed to obtain personalized BSIPs, and adjusted scaling equations, recently developed to provide the 3D position of the center of mass and both moments and products of inertia, were compared and demonstrated the same mass distribution (although significant differences). The center of mass was slightly posterior and lateral, and the products of inertia were almost of the same order as the longitudinal moment of inertia. These data may be useful for researchers who would like to obtain appropriate 3D BSIPs.
Recommended Content
Authors
Citation
Dumas, R., Verriest, J., Skalli, W., and Guise, J., "Comparison of Bi-planar Radiography and Adjusted Scaling Equations for the Computation of Appropriate 3D Body Segment Inertial Parameters," SAE Technical Paper 2006-01-2372, 2006, https://doi.org/10.4271/2006-01-2372.Also In
SAE 2006 Transactions Journal of Passenger Cars: Electronic and Electrical Systems
Number: V115-7; Published: 2007-03-30
Number: V115-7; Published: 2007-03-30
References
- Reid J. G. Jensen R. K. “Human body segment inertia parameters: a survey and status report,” Exercise and Sport Sciences Reviews 18 225 41 1990
- Pearsall D. J. Reid J. G. “The study of human body segment parameters in biomechanics. An historical review and current status report,” Sports Medicine 18 126 40 1994
- Jensen R. K. “Human morphology: its role in the mechanics of movement,” Journal of Biomechanics 26 81 94 1993
- Chandler R. F. Clauser C. E. McConville J. T. Reynolds H. M. Young J. W. “Investigation of inertial properties of the human body,” Aerospace Medical Research Laboratory, Wright-Patterson Air Force Base Dayton, Ohio Technical Report AMRL-74-137 1975
- Clauser C. E. McConville J. T. Young J. W. “Weight, volume, and center of mass of segments of the human body,” Aerospace Medical Research Laboratory, Wright-Patterson Air Force Base Dayton, Ohio Technical Report AMRL-TR-69-70 1969
- Dempster W. T. “Space requirements for the seated operator,” Wright Air Development Center, Wright-Patterson Air Force Base Dayton, Ohio WADC Technical Report TR-55-159 1955
- Zatsiorsky V. M. Seluyanov V. N. “The mass and inertia characteristics of the main segments of the human body,” Biomechanics VIII-B Matsui H. Kobayashi K. Champaign, Illinois Human Kinetics 1983 1152 9
- Durkin J. L. Dowling J. J. Andrews D. M. “The measurement of body segment inertial parameters using dual energy X-ray absorptiometry,” Journal of Biomechanics 35 1575 80 2002
- Ackland T. R. Blanksby B. A. Bloomfield J. “Inertial characteristics of adolescent male body segments,” J Biomech 21 319 27 1988
- Jensen R. K. “Estimation of the biomechanical properties of three body types using a photogrammetric method,” Journal of Biomechanics 11 349 58 1978
- McConville J. T. Churchill T. D. Kaleps I. Clauser C. E. Cuzzi J. “Anthropometric relationships of body and body segment moments of inertia,” Aerospace Medical Research Laboratory, Wright-Patterson Air Force Base Dayton, Ohio 1980
- Young J. W. Chandler R. F. Snow C. C. Robinette K. M. Zehner G. F. Lofberg M. S. “Anthropometric and mass distribution characteristics of the adult female,” FAA Civil Aeromedical Institute Oklaoma City Oklaoma Technical Report FA-AM-83-16 1983
- Sarfaty O. Ladin Z. “A video-based system for the estimation of the inertial properties of body segments,” Journal of Biomechanics 26 1011 6 1993
- Norton J. Donaldson N. Dekker L. “3D whole body scanning to determine mass properties of legs,” Journal of Biomechanics 35 81 6 2002
- Cheng C. K. Chen H. H. Chen C. S. Chen C. L. Chen C. Y. “Segment inertial properties of Chinese adults determined from magnetic resonance imaging,” Clinical Biomechanics (Bristol, Avon) 15 559 66 2000
- Pearsall D. J. Reid J. G. Ross R. “Inertial properties of the human trunk of males determined from magnetic resonance imaging,” Annals of Biomedical Engineering 22 692 706 1994
- Mungiole M. Martin P. E. “Estimating segment inertial properties: comparison of magnetic resonance imaging with existing methods,” Journal of Biomechanics 23 1039 46 1990
- Pearsall D. J. Reid J. G. Livingston L. A. “Segmental inertial parameters of the human trunk as determined from computed tomography,” Annals of Biomedical Engineering 24 198 210 1996
- Jensen R. K. “Body segment mass, radius and radius of gyration proportions of children,” Journal of Biomechanics 19 359 68 1986
- Dumas R. Aissaoui R. de Guise J. A. “A 3D generic inverse dynamic method using wrench notation and quaternion algebra,” Computer Methods in Biomechanics and Biomedical Engineering 7 159 66 2004
- Doriot N. Chèze L. “A three-dimensional kinematic and dynamic study of the lower limb during the stance phase of gait using an homogeneous matrix approach,” IEEE Transactions on Biomedical Engineering 51 21 7 2004
- Apkarian J. Naumann S. Cairns B. “A three-dimensional kinematic and dynamic model of the lower limb,” Journal of Biomechanics 22 143 55 1989
- Dumas R. Aissaoui R. Mitton D. Skalli W. de Guise J. A. “Personalized body segment parameters from bi-planar low dose radiography,” IEEE Transactions on Biomedical Engineering 52 1756 63 2005
- Mitton D. Landry C. Veron S. Skalli W. Lavaste F. De Guise J. A. “3D reconstruction method from biplanar radiography using non-stereocorresponding points and elastic deformable meshes,” Med Biol Eng Comput 38 133 9 2000
- Laporte S. Skalli W. De Guise J. A. Lavaste F. Mitton D. “A Biplanar Reconstruction Method Based on 2D and 3D Contours: Application to the Distal Femur,” Computer Methods in Biomechanics and Biomedical Engineering 6 1 6 2003
- Durkin J. L. Dowling J. J. “Analysis of body segment parameter differences between four human populations and the estimation errors of four popular mathematical models,” Journal of Biomechanical Engineering 125 515 22 2003
- de Leva P. “Adjustments to Zatsiorsky-Seluyanov's segment inertia parameters,” Journal of Biomechanics 29 1223 30 1996
- Dumas R. Chèze L. Verriest J. P. “Adjustments to McConville et al. and Young et al. body segment inertial parameters,” Journal of Biomechanics 2006
- Wu G. Siegler S. Allard P. Kirtley C. Leardini A. Rosenbaum D. Whittle M. D'Lima D. D. Cristofolini L. Witte H. Schmid O. Stokes I. “ISB recommendation on definitions of joint coordinate system of various joints for the reporting of human joint motion-part I: ankle, hip, and spine. International Society of Biomechanics,” Journal of Biomechanics 35 543 8 2002
- Wu G. van der Helm F. C. Veeger H. E. Makhsous M. Van Roy P. Anglin C. Nagels J. Karduna A. R. McQuade K. Wang X. Werner F. W. Buchholz B. “ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion-Part II: shoulder, elbow, wrist and hand,” Journal of Biomechanics 38 981 992 2005
- Clarys J. P. Marfell-Jones M. J. “Anatomical segmentation in humans and the prediction of segmental masses from intra-segmental anthropometry,” Human Biology 58 771 82 1986
- White D. R. Woodard H. Q. Hammond S. M. “Average soft-tissue and bone models for use in radiation dosimetry,” British Journal of Radiology 60 907 13 1987
- Reed M. P. Manary M. A. Schneider L. W. “Methods for measuring and representing automobile occupant posture,” Society of Automobile Engineers Warrendale, USA SAE Technical Paper Series: 1999-01-0959 1999
- Pearsall D. J. Costigan P. A. “The effect of segment parameter error on gait analysis results,” Gait and Posture 9 173 83 1999
- Rao G. Amarantini D. Berton E. Favier D. “Influence of body segments' parameters estimation models on inverse dynamics solutions during gait,” Journal of Biomechanics 2005
- Hanavan E. P. J. “A mathematical model of the human body,” Aerospace Medical Research Laboratory, Wright-Patterson Air Force Base Dayton, Ohio Technical Report AMRL-TR-64-102 1964
- Hatze H. “A mathematical model for the computational determination of parameter values of anthropomorphic segments,” Journal of Biomechanics 13 833 43 1980