This test is a case of homogeneous deformation of a cube of unit dimension. Four types of hyperelastic strain energy potentials are used: the polynomial (including the reduced polynomial and Yeoh forms, which are the most common particular cases of the general polynomial model), Ogden, Arruda-Boyce, and Van der Waals forms with coefficients drawn from Treloar's experimental data (Treloar, 1940).

Stress and strain data are entered using the *UNIAXIAL TEST DATA, *BIAXIAL TEST DATA, *PLANAR TEST DATA, and *VOLUMETRIC TEST DATA suboptions of the *HYPERELASTIC option. A least squares method is used to fit the experimental data. For the polynomial and Ogden forms the order of the series is determined by the value of the parameter N on the *HYPERELASTIC option. The following cases are analyzed:

The stress values are given in Pascals. The density of the material is 1000 kg/m³. A state of simple uniaxial tension is induced in the cube up to a strain of 600%. The stretching velocity is ramped up from zero to 6.0 m/s within 2.0 seconds. The coefficients fitted by using the polynomial strain energy potential with N=2 may lead to unstable material behavior when the nominal strain in a uniaxial tensile test reaches approximately 440%. (Unstable regimes for hyperelastic materials are discussed in “Hyperelastic behavior,” Section 10.5.1 of the ABAQUS Analysis User's Manual.) Therefore, for that particular analysis the final deformation was set to be 400% by ramping the velocity from zero to 4.2 m/s within 2.0 seconds.