Inverse parameter identification in solid mechanics using bayesian statistics, response surfaces and minimization
Article
Pacheco, CC, Dulikravich, GS, Vesenjak, M et al. (2016). Inverse parameter identification in solid mechanics using bayesian statistics, response surfaces and minimization
. 36(1-2), 120-131.
Pacheco, CC, Dulikravich, GS, Vesenjak, M et al. (2016). Inverse parameter identification in solid mechanics using bayesian statistics, response surfaces and minimization
. 36(1-2), 120-131.
This paper presents a methodology designed to calibrate a simple Finite Element (FE) model in order to accurately reproduce the mechanical behavior of a material. This desired behavior is based on experimental measurements obtained from a three-point bending test. In order to perform this inverse analysis with a feasible computational effort, the typical FE solution of the forward problem is replaced by a meta-model, based on a response surface approximation. This simplified model still allows for accurate prediction of the output of the model, but at a negligible cost. The inverse problem is solved through a Bayesian perspective, by using the Metropolis-Hastings algorithm. The results present a good agreement with results obtained by a L2-norm minimization approach, also presented here. The validation of these results is performed by running a FE simulation with the estimated parameters and the results accurately fitted the experimental data.