求解拉普拉斯方程的离散空场方程方法:边界层计算

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-02-14 DOI:10.1002/num.23092
Li-Ping Zhang, Zi‐Cai Li, Ming-Gong Lee, Hung‐Tsai Huang
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引用次数: 0

摘要

考虑有界简单连接域中拉普拉斯方程的 Dirichlet 问题 ,并使用格林表征公式的空场方程 (NFE),其中源节点位于其边界之外但不靠近其边界的伪边界上。本文利用 NFE 的中心法则提出了简单的算法,并可轻松求得边界上解的法导数。这些算法被称为离散空场方程法(DNFEM),因为配位方程实际上是 NFE 的直接离散形式。条件数的界限与基本解法(MFS)相似,随着未知数的增加而呈指数增长。DNFEM 的一个问题是,在格林表征公式中,边界层中的解的积分接近奇点。传统的 BEM 也存在同样的问题。为了解决近似奇异性问题,通常使用正交展开和 sinh 变换。然而,为了解决这一问题,我们开发了两种新技术:(I) 使用片断-度多项式和傅里叶级数的泰勒公式插值技术;(II) 积分的迷你规则,如迷你辛普森规则和迷你高斯规则。对技术 I 进行了误差分析,以达到最佳收敛率。为支持理论分析,对圆盘域进行了数值实验。DNFEM 在磁盘域的数值性能非常出色,可与 MFS 相媲美。通过组合算法可以获得与 MFS 的误差,这对于大多数工程问题来说都是令人满意的。总之,新的简单 DNFEM 基于 NFE,不同于边界元法(BEM)。本文建立了误差和稳定性的理论基础。在边界层中寻求数值解的一个难题得到了很好的解决;这也是对 BEM 的一个重要贡献。此外,数值实验也令人鼓舞。因此,DNFEM 前景广阔,有可能成为科学/工程计算的一种新边界方法。
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Discrete null field equation methods for solving Laplace's equation: Boundary layer computations
Consider Dirichlet problems of Laplace's equation in a bounded simply‐connected domain , and use the null field equation (NFE) of Green's representation formulation, where the source nodes are located on a pseudo‐boundary outside but not close to its boundary . Simple algorithms are proposed in this article by using the central rule for the NFE, and the normal derivatives of the solutions on the boundary can be easily obtained. These algorithms are called the discrete null field equation method (DNFEM) because the collocation equations are, indeed, the direct discrete form of the NFE. The bounds of the condition number are like those by the method of fundamental solutions (MFS) yielding the exponential growth as the number of unknowns increases. One trouble of the DNFEM is the near singularity of integrations for the solutions in boundary layers in Green's representation formulation. The traditional BEM also suffers from the same trouble. To deal with the near singularity, quadrature by expansions and the sinh transformation are often used. To handle this trouble, however, we develop two kinds of new techniques: (I) the interpolation techniques by Taylor's formulas with piecewise ‐degree polynomials and the Fourier series, and (II) the mini‐rules of integrals, such as the mini‐Simpson's and the mini‐Gaussian rules. Error analysis is made for technique I to achieve optimal convergence rates. Numerical experiments are carried out for disk domains to support the theoretical analysis made. The numerical performance of the DNFEM is excellent for disk domains to compete with the MFS. The errors with can be obtained by combination algorithms, which are satisfactory for most engineering problems. In summary, the new simple DNFEM is based on the NFE, which is different from the boundary element method (BEM). The theoretical basis in error and stability has been established in this article. One trouble in seeking the numerical solutions in boundary layers has been handled well; this is also an important contribution to the BEM. Besides, numerical experiments are encouraging. Hence the DNFEM is promising, and it may become a new boundary method for scientific/engineering computing.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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