MOVING FINITE ELEMENT METHOD

Boundary Elements and other Mesh Reduction Methods XLI Pub Date : 2018-09-11 DOI:10.2495/be410111

V. Sládek, M. Repka, J. Sládek

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引用次数: 7

Abstract

A novel discretization method is proposed and developed for numerical solution of boundary value problems governed by partial differential equations. The spatial variation of field variables is approximated by using Lagrange finite elements for interpolation without discretization of the analysed domain into the mesh of finite elements. Only the net of nodal points is used for discrete degrees of freedom on the analysed domain and its boundary. The governing equations are considered at interior nodal points while the boundary conditions at nodal points on the boundary. The finite elements are created for each nodal point properly instead of using fixed finite elements like in standard Finite Element Method. In this way, we can eliminate interfaces between elements as well as the difficulties with continuity of derivatives of field variables on such interfaces. Both the strong and weak formulations are implemented for governing equations. The reliability (accuracy and efficiency) of the new method has been verified in numerical simulations for 2D problems of heat conduction in solids with possible continuous gradation of the heat conduction coefficient.

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运动有限元法

提出并发展了一种新的偏微分方程边值问题数值解的离散化方法。采用拉格朗日有限元插值法逼近场变量的空间变化，而不将分析域离散到有限元网格中。在所分析的区域及其边界上，只使用节点网来表示离散自由度。内部节点处考虑控制方程，边界上节点处考虑边界条件。不同于标准有限元法中使用固定的有限元，该方法为每个节点适当地创建了有限元。这样，我们可以消除元素之间的界面，以及在这种界面上场变量导数的连续性困难。对控制方程实现了强和弱两种形式。该方法的可靠性(精度和效率)已在二维固体热传导问题的数值模拟中得到验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Boundary Elements and other Mesh Reduction Methods XLI

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