Application of radial basis function methods in the development of a 95th percentile male seated FEA model

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Vavalle, Nicholas A.; Schoell, Samantha L.; Weaver, Ashley A.; Stitzel, Joel D.; Gayzik, F. Scott

Application of radial basis function methods in the development of a 95th percentile male seated FEA model

Stapp Car Crash J. November 2014;58:361-384

©2014 The Stapp Association

Affiliations

¹Wake Forest School of Medicine

²Virginia Tech – Wake Forest University Center for Injury Biomechanics
Abstract and keywords

Human body finite element models (FEMs) are a valuable tool in the study of injury biomechanics. However, the traditional model development process can be time-consuming. Scaling and morphing an existing FEM is an attractive alternative for generating morphologically distinct models for further study. The objective of this work is to use a radial basis function to morph the Global Human Body Models Consortium (GHBMC) average male model (M50) to the body habitus of a 95th percentile male (M95) and to perform validation tests on the resulting model. The GHBMC M50 model (v. 4.3) was created using anthropometric and imaging data from a living subject representing a 50th percentile male. A similar dataset was collected from a 95th percentile male (22,067 total images) and was used in the morphing process. Homologous landmarks on the reference (M50) and target (M95) geometries, with the existing FE node locations (M50 model), were inputs to the morphing algorithm. The radial basis function was applied to morph the FE model. The model represented a mass of 103.3 kg and contained 2.2 million elements with 1.3 million nodes. Simulations of the M95 in seven loading scenarios were presented ranging from a chest pendulum impact to a lateral sled test. The morphed model matched anthropometric data to within a rootmean square difference of 4.4% while maintaining element quality commensurate to the M50 model and matching other anatomical ranges and targets. The simulation validation data matched experimental data well in most cases.

Keywords: Model morphing, Finite Element Modeling, Full human body model

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2015	Davis ML, Vavalle NA, Gayzik FS. An evaluation of mass-normalization using 50th and 95th percentile human body finite element models in frontal crash. In: Proceedings of the 2015 International IRCOBI Conference on the Biomechanics of Injury. September 9-11, 2015; Lyon, France.608-621.
2017	Hu J, Zhang K, Fanta A, Jones MLH, Reed MP, Neal M, Wang J-T, Lin C-H, Cao L. Stature and body shape effects on driver injury risks in frontal crashes: a parametric human modelling study. In: Proceedings of the 2017 International IRCOBI Conference on the Biomechanics of Injury. September 13-15, 2017; Antwerp, Belgium.656-667.
2017	Östh J, Mendoza‐Vazquez M, Linder A, Svensson MY, Brolin K. The VIVA OpenHBM finite element 50th percentile female occupant model: whole body model development and kinematic validation. In: Proceedings of the 2017 International IRCOBI Conference on the Biomechanics of Injury. September 13-15, 2017; Antwerp, Belgium.443-466.
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2016	Park G, Kim T, Forman J, Panzer MB, Crandall JR. Prediction of the structural response of the femoral shaft under dynamic bending loading using geometric subject-specific finite element models. In: Proceedings of the 12th Ohio State University Injury Biomechanics Symposium. June 5-7, 2016; Columbus, OH.
2018	Ye X, Jones D, Gaewsky J, Miller L, Stitzel J, Weaver A. Numerical analysis of driver thoracolumbar spine response in frontal crash reconstruction. In: Proceedings of the 14th Ohio State University Injury Biomechanics Symposium. May 20-22, 2018; Columbus, OH.
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2021	Yates KM, Agnew AM, Albert DL, Kemper AR, Untaroiu CD. Subject-specific rib finite element models with material data derived from coupon tests under bending loading. J Mech Behav Biomed Mater. April 2021;116:104358.
2015	Klein KF. Use of Parametric Finite Element Models to Investigate Effects of Occupant Characteristics on Lower-Extremity Injuries in Frontal Crashes [PhD thesis]. Ann Arbor, MI: University of Michigan; 2015.
2017	Park G. Injury Risk Functions Based on Responses of Population-Based Finite Element Models: Application to Femurs Under Dynamic Loading [PhD thesis]. Charlottesville, VA: University of Virginia; May 2017.
2017	Meng Y. Development and Validation of a Child Finite Element Model for Use in Pedestrian Accident Simulations [Master's thesis]. Virginia Polytechnic Institute and State University; April 28, 2017.
2019	Pak W. Development and Validation of Human Body Finite Element Models for Pedestrian Protection [PhD thesis]. Virginia Polytechnic Institute and State University; September 17, 2019.
2015	Vavalle NA. The Application of a Radial Basis Function Morphing Technique to a Validated Full Human Body Finite Element Model [PhD thesis]. Winston-Salem, NC: Wake Forest University; May 2015.
2017	Davis ML. Development and Full Body Validation of a 5th Percentile Female Finite Element Model [PhD thesis]. Winston-Salem, NC: Wake Forest University; January 2017.