Fully and sparsely supported radial basis functions

THE INTERNATIONAL JOURNAL OF COMPUTATIONAL METHODS AND EXPERIMENTAL MEASUREMENTS Pub Date : 2020-08-25 DOI:10.2495/cmem-v8-n3-208-219

E. Kansa, P. Holoborodko

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引用次数: 1

Abstract

The central idea of this paper is that computer mathematics is not identical to ideal mathematics because computer numbers only have finite precision. All functions, especially the positive definite transcendental functions, are truncated and the expansion coefficients have finite precision and all branching operations require time to complete. Of all the known methods used to obtain numerical solutions to integral and partial differential equations, the global continuously differential radial basis functions (RBFs) that are implemented on computers closely resemble many aspects of ideal mathematics. The global RBFs have the attributes required to obtain very accurate numerical results for a variety of partial differential and integral equations with smooth solutions. Without the need for extremely fine discretization, the global RBFs have their spline properties and exponential convergence rates. The resulting system of full equations can be executed very rapidly on graphical processing units and fieldprogrammable gate arrays because, with full systems, there is no branching and full systems solvers are very highly vectorized, optimizing the usage of very fast processors.

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完全和稀疏支持的径向基函数

本文的中心思想是计算机数学不等同于理想数学，因为计算机数字只有有限的精度。所有函数，特别是正定超越函数，都被截断，展开系数精度有限，所有分支操作都需要时间才能完成。在所有已知的用于获得积分和偏微分方程数值解的方法中，在计算机上实现的全局连续微分径向基函数(rbf)与理想数学的许多方面非常相似。全局rbf具有对各种具有光滑解的偏微分方程和积分方程获得非常精确的数值结果所需的属性。在不需要极精细离散化的情况下，全局rbf具有样条性质和指数收敛速度。由此产生的完整方程系统可以在图形处理单元和现场可编程门阵列上非常快速地执行，因为完整系统没有分支，并且完整系统求解器非常高度矢量化，从而优化了快速处理器的使用。

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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THE INTERNATIONAL JOURNAL OF COMPUTATIONAL METHODS AND EXPERIMENTAL MEASUREMENTS

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