基于局部核的线性算子作用近似方法的自适应性

IF 3 2区数学 Q1 MATHEMATICS, APPLIED

SIAM Journal on Scientific Computing Pub Date : 2024-08-19 DOI:10.1137/23m1598052

Jonah A. Reeger

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引用次数: 0

摘要

SIAM 科学计算期刊》，第 46 卷第 4 期，第 A2683-A2708 页，2024 年 8 月。摘要基于近似偏微分方程（PDE）解和定积分（正交/余量）求值的局部内核方法的成功经验，本文提出了对此类近似误差的局部估计。该估计值有助于确定求解域中增加节点密度（等同于减少节点间距）可减少求解误差的位置。本文介绍了一种自适应程序，用于在导数近似和定积分近似计算的域中添加节点。这种方法能有效计算一组规定点的误差估计值，并在误差过大的地方添加新节点进行近似。计算实验表明，误差估计值与近似值的实际绝对误差非常接近。在近似 PDEs 的解时（或在正交/余量的情况下），初始数据和随后的解（或积分）表现出局部特征，需要大量细化才能解决，而在整个计算域中均匀增加节点密度是不可能或过于繁琐时，这种方法是必要或可取的。

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Adaptivity in Local Kernel Based Methods for Approximating the Action of Linear Operators

SIAM Journal on Scientific Computing, Volume 46, Issue 4, Page A2683-A2708, August 2024.
Abstract. Building on the successes of local kernel methods for approximating the solutions to partial differential equations (PDEs) and the evaluation of definite integrals (quadrature/cubature), a local estimate of the error in such approximations is developed. This estimate is useful for determining locations in the solution domain where increased node density (equivalently, reduction in the spacing between nodes) can decrease the error in the solution. An adaptive procedure for adding nodes to the domain for both the approximation of derivatives and the approximate evaluation of definite integrals is described. This method efficiently computes the error estimate at a set of prescribed points and adds new nodes for approximation where the error is too large. Computational experiments demonstrate close agreement between the error estimate and actual absolute error in the approximation. Such methods are necessary or desirable when approximating solutions to PDEs (or in the case of quadrature/cubature), where the initial data and subsequent solution (or integrand) exhibit localized features that require significant refinement to resolve and where uniform increases in the density of nodes across the entire computational domain is not possible or too burdensome.

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来源期刊

SIAM Journal on Scientific Computing 数学-应用数学

CiteScore

5.50

自引率

3.20%

发文量

209

审稿时长

1 months

期刊介绍： The purpose of SIAM Journal on Scientific Computing (SISC) is to advance computational methods for solving scientific and engineering problems. SISC papers are classified into three categories: 1. Methods and Algorithms for Scientific Computing: Papers in this category may include theoretical analysis, provided that the relevance to applications in science and engineering is demonstrated. They should contain meaningful computational results and theoretical results or strong heuristics supporting the performance of new algorithms. 2. Computational Methods in Science and Engineering: Papers in this section will typically describe novel methodologies for solving a specific problem in computational science or engineering. They should contain enough information about the application to orient other computational scientists but should omit details of interest mainly to the applications specialist. 3. Software and High-Performance Computing: Papers in this category should concern the novel design and development of computational methods and high-quality software, parallel algorithms, high-performance computing issues, new architectures, data analysis, or visualization. The primary focus should be on computational methods that have potentially large impact for an important class of scientific or engineering problems.