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Shape functions of superconvergent finite element models
Abstract In structural dynamics superconvergent element models are obtained by eigen-value convergence analysis, or minimizing the discretization errors leading to maximum convergence rates in their eigen-solutions. The element formulations developed by these inverse strategies are obtained in local coordinates. As no shape functions are employed in their development transforming them to global coordinates is a challenge and prevents their use in practical finite element models. To remove this obstacle a new method is proposed to obtain shape functions for superconvergent element models attained directly from the eigen-value convergence analysis or discretization error analysis. The method employs series of trigonometric functions to obtain shape functions corresponding to the superconvergent element formulations. Using the proposed strategy, the shape functions for superconvergent rod, beam and transverse vibration membrane are obtained. It is shown transformation of the superconvergent element formulation to the global coordinates using the obtained shape functions does not affect the eigen-value convergence rates.
Highlights ► Trigonometric functions are employed to form shape functions of superconvergent element models. ► The shape functions are used to transform the element displacement field to the global coordinates. ► Improvements in estimating the eigen-values are demonstrated in a sectorial vibrating membrane. ► It is shown the accuracy of model is kept unchanged in global coordinates. ► Also higher order of accuracy is achieved compared to the existing formulations in the literature.
Shape functions of superconvergent finite element models
Abstract In structural dynamics superconvergent element models are obtained by eigen-value convergence analysis, or minimizing the discretization errors leading to maximum convergence rates in their eigen-solutions. The element formulations developed by these inverse strategies are obtained in local coordinates. As no shape functions are employed in their development transforming them to global coordinates is a challenge and prevents their use in practical finite element models. To remove this obstacle a new method is proposed to obtain shape functions for superconvergent element models attained directly from the eigen-value convergence analysis or discretization error analysis. The method employs series of trigonometric functions to obtain shape functions corresponding to the superconvergent element formulations. Using the proposed strategy, the shape functions for superconvergent rod, beam and transverse vibration membrane are obtained. It is shown transformation of the superconvergent element formulation to the global coordinates using the obtained shape functions does not affect the eigen-value convergence rates.
Highlights ► Trigonometric functions are employed to form shape functions of superconvergent element models. ► The shape functions are used to transform the element displacement field to the global coordinates. ► Improvements in estimating the eigen-values are demonstrated in a sectorial vibrating membrane. ► It is shown the accuracy of model is kept unchanged in global coordinates. ► Also higher order of accuracy is achieved compared to the existing formulations in the literature.
Shape functions of superconvergent finite element models
Ahmadian, Hamid (author) / Farughi, Shirko (author)
Thin-Walled Structures ; 49 ; 1178-1183
2011-05-16
6 pages
Article (Journal)
Electronic Resource
English
Shape functions of superconvergent finite element models
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