Since the deformation tensor F is a two-point tensor, it combines both spatial and material frames. It is not symmetric. Applying a singular value decomposition on the deformation gradient tensor gives an insight into how much stretch and rotation a unit volume of material has been subjected to. The right polar decomposition is defined as

where R is a proper orthogonal tensor (, and ) and U is the right stretch tensor given in the material frame. The rotation tensor R describes the rigid rotation, and all information about the deformation of the material is contained in the symmetric tensor U.

The stretch tensor contains physically important information about the deformation state. The eigenvalues of the U tensor are the principal stretches, λ1, λ2, and λ3. The stretch of a line element with initial length L0 and current length L is

where εeng is the engineering strain. The three principal stretches act along three orthogonal directions. In the coordinate system defined by these principal directions, the U tensor will be diagonal:

The right Cauchy-Green deformation tensor C defined by

It is a symmetric and positive definite tensor, which accounts for the strain but not for the rotation. The eigenvalues of the C tensor are the squared principal stretches, thus providing a more efficient way to compute the principal stretches than by using the stretch tensor U directly.

The Green-Lagrange strain tensor is a symmetric tensor defined as

Since C is independent of rigid body rotations, this applies also to the Green-Lagrange strain tensor.

In COMSOL Multiphysics, the tensor form of strain representation (εxy, εyz, εxz) is used.

The symmetric strain tensor ε consists of both normal and shear strain components:

A general description of the axially symmetric case is given in Axial Symmetry and Deformation.