Finite element analysis in functional morphology. Academic Article

abstract

• This article reviews the fundamental principles of the finite element method and the three basic steps (model creation, solution, and validation and interpretation) involved in using it to examine structural mechanics. Validation is a critical step in the analysis, without which researchers cannot evaluate the extent to which the model represents or is relevant to the real biological condition. We discuss the method's considerable potential as a tool to test biomechanical hypotheses, and major hurdles involved in doing so reliably, from the perspective of researchers interested in functional morphology and paleontology. We conclude with a case study to illustrate how researchers deal with many of the factors and assumptions involved in finite element analysis.

authors

• Dechow, Paul

published proceedings

• Anat Rec A Discov Mol Cell Evol Biol

author list (cited authors)

• Richmond, B. G., Wright, B. W., Grosse, I., Dechow, P. C., Ross, C. F., Spencer, M. A., & Strait, D. S

citation count

• 165

complete list of authors

• Richmond, Brian G||Wright, Barth W||Grosse, Ian||Dechow, Paul C||Ross, Callum F||Spencer, Mark A||Strait, David S

publication date

• April 2005

publisher

• Wiley  Publisher

published in

• n1552-4884ISSN  Journal

keywords

• Anatomy
• Animals
• Biomechanical Phenomena
• Biomechanics
• Body Patterning
• Computer Simulation
• Fimctional Morphology
• Finite Element Analysis
• Finite-element Analysis
• Humans
• Mastication
• Models, Biological
• Paleoanthropology
• Primates
• Reproducibility Of Results

PubMed Central ID

• 15747355

Digital Object Identifier (DOI)

• 10.1002/ar.a.20169

start page

• 259

end page

• 274

volume

• 283

issue

• 2

URL

• http://dx.doi.org/10.1002/ar.a.20169