A finite element reduced-order model based on adaptive mesh refinement and artificial neural networks
In this work, a reduced-order model based on adaptive finite element meshes and a correction term obtained by using an artificial neural network (FAN-ROM) is presented. The idea is to run a high-fidelity simulation by using an adaptively refined finite element mesh and compare the results obtained with those of a coarse mesh finite element model. From this comparison, a correction forcing term can be computed for each training configuration. A model for the correction term is built by using an artificial neural network, and the final reduced-order model is obtained by putting together the coarse mesh finite element model, plus the artificial neural network model for the correction forcing term. The methodology is applied to nonlinear solid mechanics problems, transient quasi-incompressible flows, and a fluid-structure interaction problem. The results of the numerical examples show that the FAN-ROM is capable of improving the simulation results obtained in coarse finite element meshes at a reduced computational cost.
|Título según WOS:||A finite element reduced-order model based on adaptive mesh refinement and artificial neural networks|
|Título según SCOPUS:||A finite element reduced-order model based on adaptive mesh refinement and artificial neural networks|
|Título de la Revista:||INTERNATIONAL JOURNAL FOR NUMERICAL METHODS IN ENGINEERING|
|Fecha de publicación:||2020|
|Página de inicio:||588|