边值问题的拉格朗日径向基函数配置方法

IF 1.8 3区 数学 Q1 MATHEMATICS
Kawther Al Arfaj, Jeremy Levesly
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引用次数: 0

摘要

>& gt;& gt;& gt;& gt;& gt;本文介绍了径向基函数拉格朗日配置法(LRBF)作为求解一维偏微分方程的一种新方法。我们的方法解决了权衡原则,这是标准RBF配置方法面临的一个关键挑战,通过保持数值解的准确性和收敛性,同时提高了稳定性和效率。证明了特定微分算子(如拉普拉斯算子)和正定rbf数值解的存在唯一性。此外,我们在主矩阵中引入了扰动,从而发展了扰动LRBF方法(PLRBF);这允许应用Cholesky分解,这显着减少了矩阵的条件数到它的平方根,从而产生CPLRBF方法。反过来,这使我们能够在不影响稳定性和精度的情况下为形状参数选择一个大的值,前提是仔细选择扰动。通过这样做,可以在早期级别实现高度精确的解决方案,从而显着减少中央处理单元(CPU)时间。此外,为了克服RBF配置方法存在的滞滞问题,我们将LRBF和CPLRBF与多级技术相结合,得到了多级PLRBF (MuCPLRBF)技术。我们用一维泊松方程的数值实验说明了所提出方法的稳定性、准确性、收敛性和效率。虽然我们的方法是针对一维的,但我们希望能够在未来的工作中将其扩展到更高的维度。</p></abstract>
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Lagrange radial basis function collocation method for boundary value problems in $ 1 $D

This paper introduces the Lagrange collocation method with radial basis functions (LRBF) as a novel approach to solving 1D partial differential equations. Our method addresses the trade-off principle, which is a key challenge in standard RBF collocation methods, by maintaining the accuracy and convergence of the numerical solution, while improving the stability and efficiency. We prove the existence and uniqueness of the numerical solution for specific differential operators, such as the Laplacian operator, and for positive definite RBFs. Additionally, we introduce a perturbation into the main matrix, thereby developing the perturbed LRBF method (PLRBF); this allows for the application of Cholesky decomposition, which significantly reduces the condition number of the matrix to its square root, resulting in the CPLRBF method. In return, this enables us to choose a large value for the shape parameter without compromising stability and accuracy, provided that the perturbation is carefully selected. By doing so, highly accurate solutions can be achieved at an early level, significantly reducing central processing unit (CPU) time. Furthermore, to overcome stagnation issues in the RBF collocation method, we combine LRBF and CPLRBF with multilevel techniques and obtain the Multilevel PLRBF (MuCPLRBF) technique. We illustrate the stability, accuracy, convergence, and efficiency of the presented methods in numerical experiments with a 1D Poisson equation. Although our approach is presented for 1D, we expect to be able to extend it to higher dimensions in future work.

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来源期刊
AIMS Mathematics
AIMS Mathematics Mathematics-General Mathematics
CiteScore
3.40
自引率
13.60%
发文量
769
审稿时长
90 days
期刊介绍: AIMS Mathematics is an international Open Access journal devoted to publishing peer-reviewed, high quality, original papers in all fields of mathematics. We publish the following article types: original research articles, reviews, editorials, letters, and conference reports.
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