A Fast Element-Free Galerkin Method for 3D Elasticity Problems

In this paper, a fast element-free Galerkin (FEFG) method for three-dimensional (3D) elasticity problems is established. The FEFG method is a combination of the improved element-free Galerkin (IEFG) method and the dimension splitting method (DSM). By using the DSM, a 3D problem is converted to a series of 2D ones, and the IEFG method with a weighted orthogonal function as the basis function and the cubic spline function as the weight function is applied to simulate these 2D problems. The essential boundary conditions are treated by the penalty method. The splitting direction uses the finite difference method (FDM), which can combine these 2D problems into a discrete system. Finally, the system equation of the 3D elasticity problem is obtained. Some specific numerical problems are provided to illustrate the effectiveness and advantages of the FEFG method for 3D elasticity by comparing the results of the FEFG method with those of the IEFG method. The convergence and relative error norm of the FEFG method for elasticity are also studied.

Automated summary

In this paper, a fast FEFG method is proposed for solving 3D elasticity problems. The method combines the IEFG method and the DSM, and converts the 3D problem into a series of 2D problems. The effectiveness and advantages of the FEFG method are demonstrated through numerical experiments, and the convergence and relative error norm of the method are studied.