Development of an inverse identification method for identifying constitutive parameters by metaheuristic optimization algorithm: Application to hyperelastic materials
G Bastos (IPR), A Tayeb (IPR), N. Di Cesare (IRTES - M3M), Jean-Benoit, Le Cam (IPR), E Robin (IPR)

TL;DR
This paper presents a novel inverse identification method using a metaheuristic optimization algorithm, specifically Particle Swarm Optimization, to determine hyperelastic material parameters from full kinematic field measurements and FE simulations.
Contribution
It introduces a new approach combining FE simulations, full-field measurements, and a metaheuristic algorithm for hyperelastic parameter identification, reducing the need for multiple homogeneous tests.
Findings
Effective identification of hyperelastic parameters from heterogeneous tests
Utilization of Particle Swarm Optimization based on PageRank algorithm
Successful application to surface kinematic data from cruciform specimens
Abstract
In the present study, a numerical method based on a metaheuristic parametric algorithm has been developed to identify the constitutive parameters of hyperelastic models, by using FE simulations and full kinematic field measurements. The full kinematic field is measured at the surface of a cruciform specimen submitted to equibiaxial tension. The sample is reconstructed by FE to obtain the numerical kinematic field to be compared with the experimental one. The constitutive parameters used in the numerical model are then modified through the optimization process, for the numerical kinematic field to fit with the experimental one. The cost function is then formulated as the minimization of the difference between these two kinematic fields. The optimization algorithm is an adaptation of the Particle Swarm Optimization algorithm, based on the PageRank algorithm used by the famous search…
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