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Adaptive mesh refinement of the boundary element method for potential problems by using mesh sensitivities as error indicators

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Abstract

This paper presents a novel method for error estimation and h-version adaptive mesh refinement for potential problems which are solved by the boundary element method (BEM). Special sensitivities, denoted as mesh sensitivities, are used to evaluate a posteriori error indicators for each element, and a global error estimator. A mesh sensitivity is the sensitivity of a physical quantity at a boundary node with respect to perturbation of the mesh. The element error indicators for all the elements can be evaluated from these mesh sensitivities. Mesh refinement can then be performed by using these element error indicators as guides.

The method presented here is suitable for both potential and elastostatics problems, and can be applied for adaptive mesh refinement with either linear or quadratic boundary elements. For potential problems, the physical quantities are potential and/or flux; for elastostatics problems, the physical quantities are tractions/displacements (or tangential derivatives of displacements). In this paper, the focus is on potential problems with linear elements, and the proposed method is validated with two illustrative examples. However, it is easy to extend these ideas to elastostatics problems and to quadratic elements.

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Authors and Affiliations

  1. Department of Theoretical and Applied Mechanics, Cornell University, 14853, Ithaca, NY, USA

    F. Shi & S. Mukherjee

  2. Xerox Corp., Design Research Institute, 502 Engineering and Theory Center, Cornell University, 14853, Ithaca, NY, USA

    P. Ramesh

Authors
  1. F. Shi
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  2. P. Ramesh
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  3. S. Mukherjee
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Additional information

Communicated by T. A. Cruse, 12 July 1995

The computing for this research has been supported by the Cornell National Supercomputer Facility.

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Shi, F., Ramesh, P. & Mukherjee, S. Adaptive mesh refinement of the boundary element method for potential problems by using mesh sensitivities as error indicators. Computational Mechanics 16, 379–395 (1995). https://doi.org/10.1007/BF00370560

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