One-point quadrature of higher-order finite and virtual elements in nonlinear analysis

Author:

Bode TobiasORCID

Abstract

AbstractIn the present article, a stability- and consistency-preserving integration scheme for polynomial Galerkin approaches of arbitrary order is presented. The basis is formed by Taylor series expansions of the stresses with respect to the strains, which in turn are expanded towards the spatial directions. With a split of the material and geometric nonlinearities and the assumption of a material behavior linearly variable within an element, the strain energy in elements of arbitrary shape and polynomial order can be evaluated exactly. Therefore, geometric moments have to be calculated in preprocessing, requiring only evaluations of derivatives at a single integration point during the analysis. The moments can be effectively integrated analytically over the boundary of the elements. As one of the manifold applications, the use in the context of second order virtual elements is elaborated for which the assembly time can be significantly reduced. The combination with the automatic differentiation and expression optimization software AceGen provides performant element routines. In the numerical examples, the integration scheme shows promising accuracy and makes the application in more complex material models up to computational homogenization attractive.

Funder

Deutsche Forschungsgemeinschaft

Publisher

Springer Science and Business Media LLC

Subject

Applied Mathematics,Computational Mathematics,Computational Theory and Mathematics,Mechanical Engineering,Ocean Engineering,Computational Mechanics

Reference40 articles.

1. Céa J (1964) Approximation variationnelle des problèmes aux limites 14:345–444

2. Bathe K-J (2006) Finite element procedures. Klaus-Jürgen Bathe

3. Davis PJ, Rabinowitz P (2007) Methods of numerical integration. Dover Publications

4. Hildebrand FB (1987) Introduction to numerical analysis. Courier Corporation

5. Malkus DS, Hughes TJR (1978) Mixed finite element methods—reduced and selective integration techniques: a unification of concepts. Comput Methods Appl Mech Eng 15(1):63–81

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