Finite Strain Homogenization Using a Reduced Basis and Efficient Sampling
For researchers in multiscale mechanics, this method offers a practical surrogate that significantly reduces computational cost while maintaining accuracy, though it is an incremental improvement over existing reduced-order techniques.
The paper tackles computational homogenization of hyperelastic solids at finite strains, achieving speed-up factors of 5-100 with improved robustness and good accuracy using a reduced basis method based on deformation gradient fluctuations and efficient sampling via Hencky strain.
The computational homogenization of hyperelastic solids in the geometrically nonlinear context has yet to be treated with sufficient efficiency in order to allow for real-world applications in true multiscale settings. This problem is addressed by a problem-specific surrogate model founded on a reduced basis approximation of the deformation gradient on the microscale. The setup phase is based upon a snapshot POD on deformation gradient fluctuations, in contrast to the widespread displacement-based approach. In order to reduce the computational offline costs, the space of relevant macroscopic stretch tensors is sampled efficiently by employing the Hencky strain. Numerical results show speed-up factors in the order of 5-100 and significantly improved robustness while retaining good accuracy. An open-source demonstrator tool with 50 lines of code emphasizes the simplicity and efficiency of the method.