Advanced elasticity/Ogden material

The Ogden material model is a w:hyperelastic material model used to describe the non-linear stress-strain behaviour of complex materials such as rubbers, w:polymers, and w:biological tissue. The model was developed by w:Ray W. Ogden in 1972. ^[1] The Ogden model, like other w:hyperelastic material models, assumes that the material behaviour can be described by means of a strain energy density function, from which the stress-strain relationships can be derived. These materials can generally be considered to be w:isotropic, w:incompressible and w:strain rate independent.

In the Ogden material model, the strain energy density is expressed in terms of the principal stretches ${\displaystyle {\lambda }_j}$, ${\displaystyle j=1,2,3}$ as:

${\displaystyle W({\lambda }_1,{\lambda }_2,{\lambda }_3)={\displaystyle \sum _{p=1}^N}\frac{{\mu }_p}{{\alpha }_p}({\lambda }_1^{{\alpha }_p}+{\lambda }_2^{{\alpha }_p}+{\lambda }_3^{{\alpha }_p}-3)}$

where ${\displaystyle N}$, ${\displaystyle {\mu }_p}$ and ${\displaystyle {\alpha }_p}$ are material constants. Under the assumption of incompressibility one can rewrite as

${\displaystyle W({\lambda }_1,{\lambda }_2)={\displaystyle \sum _{p=1}^N}\frac{{\mu }_p}{{\alpha }_p}({\lambda }_1^{{\alpha }_p}+{\lambda }_2^{{\alpha }_p}+{\lambda }_1^{-{\alpha }_p}{\lambda }_2^{-{\alpha }_p}-3)}$

In general the shear modulus results from

${\displaystyle 2\mu ={\displaystyle \sum _{p=1}^N}{\mu }_p{\alpha }_p.}$

With ${\displaystyle N=3}$ and by fitting the material parameters, the material behaviour of rubbers can be described very accurately. For particular values of material constants, the Ogden model will reduce to either the w:Neo-Hookean solid(${\displaystyle N=1}$, ${\displaystyle \alpha =2}$) or the Mooney-Rivlin material (${\displaystyle N=2}$, ${\displaystyle {\alpha }_1=2}$, ${\displaystyle {\alpha }_2=-2}$).

Using the Ogden material model, the three principal values of the Cauchy stresses can now be computed as

${\displaystyle {\sigma }_{\alpha }=p+{\lambda }_{\alpha }\frac{\partial W}{\partial {\lambda }_{\alpha }}}$

where use is made of ${\displaystyle {\sigma }_{\alpha }={\lambda }_{\alpha }{P}_{\alpha }}$.

We now consider an incompressible material under uniaxial tension, with the stretch ratio given as ${\displaystyle \lambda =\frac{l}{l_0}}$. The principal stresses are given by

${\displaystyle {\sigma }_{\alpha }=p+{\displaystyle \sum _{p=1}^N}{\mu }_p{\lambda }_p^{{\alpha }_p}}$

The pressure ${\displaystyle p}$ is determined from incompressibility and boundary condition ${\displaystyle {\sigma }_2={\sigma }_3=0}$, yielding:

${\displaystyle {\sigma }_{\alpha }={\displaystyle \sum _{p=1}^N}({\mu }_p{\lambda }_p^{{\alpha }_p}-{\mu }_p{\lambda }_p^{\frac{1}{2}{\alpha }_p})}$

There exist many models to describe hyperelastic behaviour, each starting from a given strain-energy density function. In practice, however, the Ogden material model has become the reference material law for describing the behaviour of natural rubbers as it combines accuracy with computational simplicity.

• F. Cirak: Lecture Notes for 5R14: Non-linear solid mechanics, University of Cambridge.
• R.W. Ogden: Non-Linear Elastic Deformations, Template:ISBN
• K. Weinberg: Lecture Notes for Zur Methode der finiten Elemente in der Mechanik II: Nichtlineare Probleme, TU Berlin [in English].
  http://mechanik.tu-berlin.de/weinberg/Lehre/fem2/Chapter4.pdf

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