Computational Homogenisation and Identification of Auxetic Structures with Interval Parameters.

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Title: Computational Homogenisation and Identification of Auxetic Structures with Interval Parameters.
Authors: Beluch, Witold1 (AUTHOR) witold.beluch@polsl.pl, Hatłas, Marcin2 (AUTHOR), Ptaszny, Jacek1,3 (AUTHOR), Kloc-Ptaszna, Anna1,3 (AUTHOR)
Source: Materials (1996-1944). Oct2025, Vol. 18 Issue 19, p4554. 21p.
Subjects: Auxetic materials, Interval analysis, Multi-objective optimization, Multiscale modeling, Materials analysis, Nonlinear mechanics, Finite element method
Abstract: The subject of this paper is the computational homogenisation and identification of heterogeneous materials in the form of auxetic structures made of materials with nonlinear characteristics. It is assumed that some of the material and topological parameters of the auxetic structures are uncertain and are modelled as interval numbers. Directed interval arithmetic is used to minimise the width of the resulting intervals. The finite element method is employed to solve the boundary value problem, and artificial neural network response surfaces are utilised to reduce the computational effort. In order to solve the identification task, the Pareto approach is adopted, and a multi-objective evolutionary algorithm is used as the global optimisation method. The results obtained from computational homogenisation under uncertainty demonstrate the efficacy of the proposed methodology in capturing material behaviour, thereby underscoring the significance of incorporating uncertainty into material properties. The identification results demonstrate the successful identification of material parameters at the microscopic scale from macroscopic data involving the interval description of the process of deformation of auxetic structures in a nonlinear regime. [ABSTRACT FROM AUTHOR]
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Abstract:The subject of this paper is the computational homogenisation and identification of heterogeneous materials in the form of auxetic structures made of materials with nonlinear characteristics. It is assumed that some of the material and topological parameters of the auxetic structures are uncertain and are modelled as interval numbers. Directed interval arithmetic is used to minimise the width of the resulting intervals. The finite element method is employed to solve the boundary value problem, and artificial neural network response surfaces are utilised to reduce the computational effort. In order to solve the identification task, the Pareto approach is adopted, and a multi-objective evolutionary algorithm is used as the global optimisation method. The results obtained from computational homogenisation under uncertainty demonstrate the efficacy of the proposed methodology in capturing material behaviour, thereby underscoring the significance of incorporating uncertainty into material properties. The identification results demonstrate the successful identification of material parameters at the microscopic scale from macroscopic data involving the interval description of the process of deformation of auxetic structures in a nonlinear regime. [ABSTRACT FROM AUTHOR]
ISSN:19961944
DOI:10.3390/ma18194554