Solution of the Poisson equation by the boundary integral method

IF 4 3区 工程技术 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS International Journal of Numerical Methods for Heat & Fluid Flow Pub Date : 2024-08-22 DOI:10.1108/hff-04-2024-0251
Sandipan Kumar Das
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引用次数: 0

Abstract

Purpose

The boundary integral method (BIM) is very attractive to practicing engineers as it reduces the dimensionality of the problem by one, thereby making the procedure computationally inexpensive compared to its peers. The principal feature of this technique is the limitation of all its computations to only the boundaries of the domain. Although the procedure is well developed for the Laplace equation, the Poisson equation offers some computational challenges. Nevertheless, the literature provides a couple of solution methods. This paper revisits an alternate approach that has not gained much traction within the community. The purpose of this paper is to address the main bottleneck of that approach in an effort to popularize it and critically evaluate the errors introduced into the solution by that method.

Design/methodology/approach

The primary intent in the paper is to work on the particular solution of the Poisson equation by representing the source term through a Fourier series. The evaluation of the Fourier coefficients requires a rectangular domain even though the original domain can be of any arbitrary shape. The boundary conditions for the homogeneous solution gets modified by the projection of the particular solution on the original boundaries. The paper also develops a new Gauss quadrature procedure to compute the integrals appearing in the Fourier coefficients in case they cannot be analytically evaluated.

Findings

The current endeavor has developed two different representations of the source terms. A comprehensive set of benchmark exercises has successfully demonstrated the effectiveness of both the methods, especially the second one. A subsequent detailed analysis has identified the errors emanating from an inadequate number of boundary nodes and Fourier modes, a high difference in sizes between the particular solution and the original domains and the used Gauss quadrature integration procedures. Adequate mitigation procedures were successful in suppressing each of the above errors and in improving the solution accuracy to any desired level. A comparative study with the finite difference method revealed that the BIM was as accurate as the FDM but was computationally more efficient for problems of real-life scale. A later exercise minutely analyzed the heat transfer physics for a fin after validating the simulation results with the analytical solution that was separately derived. The final set of simulations demonstrated the applicability of the method to complicated geometries.

Originality/value

First, the newly developed Gauss quadrature integration procedure can efficiently compute the integrals during evaluation of the Fourier coefficients; the current literature lacks such a tool, thereby deterring researchers to adopt this category of methods. Second, to the best of the author’s knowledge, such a comprehensive error analysis of the solution method within the BIM framework for the Poisson equation does not currently exist in the literature. This particular exercise should go a long way in increasing the confidence of the research community to venture into this category of methods for the solution of the Poisson equation.

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用边界积分法求解泊松方程
目的 边界积分法(BIM)对实际工程师非常有吸引力,因为它将问题的维数减少了一维,从而使程序的计算成本低于同类方法。该技术的主要特点是其所有计算仅限于域的边界。虽然该程序在拉普拉斯方程方面发展成熟,但在泊松方程方面却面临一些计算上的挑战。不过,文献中提供了一些求解方法。本文重新审视了一种在业界尚未获得广泛关注的替代方法。本文的目的是解决该方法的主要瓶颈,努力推广该方法,并对该方法在求解过程中引入的误差进行批判性评估。 设计/方法/途径 本文的主要意图是通过傅里叶级数来表示源项,从而解决泊松方程的特殊问题。傅里叶系数的计算需要一个矩形域,尽管原始域可以是任意形状。同质解的边界条件通过特定解在原始边界上的投影进行修改。本文还开发了一种新的高斯正交程序,用于计算傅里叶系数中出现的积分,以防无法对其进行分析评估。一套全面的基准练习成功证明了这两种方法的有效性,尤其是第二种方法。随后的详细分析确定了错误源于边界节点和傅立叶模式数量不足、特定解决方案和原始域之间的尺寸差异过大以及所使用的高斯正交积分过程。适当的缓解程序成功地抑制了上述误差,并将求解精度提高到所需水平。与有限差分法的比较研究表明,BIM 与有限差分法一样精确,但对于现实生活中的问题,BIM 的计算效率更高。在将模拟结果与单独得出的分析解决方案进行验证后,随后的练习对鳍片的传热物理学进行了细致分析。原创性/价值首先,新开发的高斯正交积分过程可以在评估傅里叶系数时高效计算积分;目前的文献缺乏这样的工具,因此阻碍了研究人员采用这类方法。其次,就作者所知,目前还没有文献对泊松方程 BIM 框架内的求解方法进行如此全面的误差分析。这项工作应能大大增强研究界的信心,使其大胆采用这类方法来求解泊松方程。
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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来源期刊
CiteScore
9.50
自引率
11.90%
发文量
100
审稿时长
6-12 weeks
期刊介绍: The main objective of this international journal is to provide applied mathematicians, engineers and scientists engaged in computer-aided design and research in computational heat transfer and fluid dynamics, whether in academic institutions of industry, with timely and accessible information on the development, refinement and application of computer-based numerical techniques for solving problems in heat and fluid flow. - See more at: http://emeraldgrouppublishing.com/products/journals/journals.htm?id=hff#sthash.Kf80GRt8.dpuf
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