A Family of Inertial Three‐Term CGPMs for Large‐Scale Nonlinear Pseudo‐Monotone Equations With Convex Constraints

IF 1.8 3区数学 Q1 MATHEMATICS

Numerical Linear Algebra with Applications Pub Date : 2024-09-11 DOI:10.1002/nla.2589

Jinbao Jian, Qiongxuan Huang, Jianghua Yin, Guodong Ma

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引用次数: 0

Abstract

This article presents and analyzes a family of three‐term conjugate gradient projection methods with the inertial technique for solving large‐scale nonlinear pseudo‐monotone equations with convex constraints. The generated search direction exhibits good properties independent of line searches. The global convergence of the family is proved without the Lipschitz continuity of the underlying mapping. Furthermore, under the locally Lipschitz continuity assumption, we conduct a thorough analysis related to the asymptotic and non‐asymptotic global convergence rates in terms of iteration complexity. To our knowledge, this is the first iteration‐complexity analysis for inertial gradient‐type projection methods, in the literature, under such a assumption. Numerical experiments demonstrate the computational efficiency of the family, showing its superiority over three existing inertial methods. Finally, we apply the proposed family to solve practical problems such as ‐regularized logistic regression, sparse signal restoration and image restoration problems, highlighting its effectiveness and potential for real‐world applications.

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具有凸约束条件的大规模非线性伪单调方程的惯性三期 CGPM 族

本文介绍并分析了一系列三项共轭梯度投影方法，这些方法采用惯性技术，用于求解带凸约束的大规模非线性伪单调方程。生成的搜索方向具有独立于直线搜索的良好特性。在底层映射不存在 Lipschitz 连续性的情况下，证明了该族的全局收敛性。此外，在局部 Lipschitz 连续性假设下，我们对迭代复杂度的渐近和非渐近全局收敛率进行了深入分析。据我们所知，这是文献中首次在这种假设下对惯性梯度型投影方法进行迭代复杂性分析。数值实验证明了该族的计算效率，显示出它优于现有的三种惯性方法。最后，我们将所提出的族应用于解决实际问题，如规则化逻辑回归、稀疏信号恢复和图像复原问题，突出了它在实际应用中的有效性和潜力。

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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来源期刊

Numerical Linear Algebra with Applications 数学-数学

CiteScore

3.40

自引率

2.30%

发文量

审稿时长

12 months

期刊介绍： Manuscripts submitted to Numerical Linear Algebra with Applications should include large-scale broad-interest applications in which challenging computational results are integral to the approach investigated and analysed. Manuscripts that, in the Editor’s view, do not satisfy these conditions will not be accepted for review. Numerical Linear Algebra with Applications receives submissions in areas that address developing, analysing and applying linear algebra algorithms for solving problems arising in multilinear (tensor) algebra, in statistics, such as Markov Chains, as well as in deterministic and stochastic modelling of large-scale networks, algorithm development, performance analysis or related computational aspects. Topics covered include: Standard and Generalized Conjugate Gradients, Multigrid and Other Iterative Methods; Preconditioning Methods; Direct Solution Methods; Numerical Methods for Eigenproblems; Newton-like Methods for Nonlinear Equations; Parallel and Vectorizable Algorithms in Numerical Linear Algebra; Application of Methods of Numerical Linear Algebra in Science, Engineering and Economics.