平稳迭代法舍入误差验证分析

2022 IEEE/ACM Sixth International Workshop on Software Correctness for HPC Applications (Correctness) Pub Date : 2022-11-01 DOI:10.1109/Correctness56720.2022.00007

Ariel E. Kellison, Mohit Tekriwal, Jean-Baptiste Jeannin, G. Hulette

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引用次数: 1

摘要

求解线性系统的迭代方法是计算科学的基本组成部分。这些方法的计算成本可能会受到由于它们在有限精度下实现而累积的舍入误差的显著影响。在极端情况下，实践中出现的舍入错误可能会完全阻止实现满足其底层算法规定的精度和收敛行为。在成本至上的百亿亿次时代，不应忽视对舍入导致的收敛延迟进行彻底而严格的分析。本文利用一个小模型问题和Jacobi迭代方法，证明了Coq证明助手可以形式化地指定迭代方法的浮点行为，并严格证明了这些方法的准确性。

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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Towards Verified Rounding Error Analysis for Stationary Iterative Methods

Iterative methods for solving linear systems serve as a basic building block for computational science. The computational cost of these methods can be significantly influenced by the round-off errors that accumulate as a result of their implementation in finite precision. In the extreme case, round-off errors that occur in practice can completely prevent an implementation from satisfying the accuracy and convergence behavior prescribed by its underlying algorithm. In the exascale era where cost is paramount, a thorough and rigorous analysis of the delay of convergence due to round-off should not be ignored. In this paper, we use a small model problem and the Jacobi iterative method to demonstrate how the Coq proof assistant can be used to formally specify the floating-point behavior of iterative methods, and to rigorously prove the accuracy of these methods.

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2022 IEEE/ACM Sixth International Workshop on Software Correctness for HPC Applications (Correctness)

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