解决广义张量特征值问题的归一化牛顿法

IF 1.8 3区数学 Q1 MATHEMATICS

Numerical Linear Algebra with Applications Pub Date : 2024-01-09 DOI:10.1002/nla.2547

Mehri Pakmanesh, Hamidreza Afshin, Masoud Hajarian

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引用次数: 0

摘要

广义张量特征值问题是本文的重点。为了解决这个问题，我们建议使用归一化牛顿广义特征问题方法（NNGEM）。由于频谱梯度投影法（SGP）、广义特征问题自适应功率法（GEAP）和其他方法的收敛速度只是线性的，而我们提出的方法能显著改善它们的收敛速度，并证明其具有局部收敛性和立方收敛性。此外，改进的归一化牛顿法（MNNM）在相同的 γ$$ \gamma $$-Newton 稳定性要求下收敛于对称张量 Z 特征对，该方法由 NNGEM 技术扩展而来。多项式系统求解器（NSolve）使用格罗布纳基，为我们生成所有实特征值。为了说明我们的方法的有效性，我们给出了一些数值结果。

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Normalized Newton method to solve generalized tensor eigenvalue problems

The problem of generalized tensor eigenvalue is the focus of this paper. To solve the problem, we suggest using the normalized Newton generalized eigenproblem approach (NNGEM). Since the rate of convergence of the spectral gradient projection method (SGP), the generalized eigenproblem adaptive power (GEAP), and other approaches is only linear, they are significantly improved by our proposed method, which is demonstrated to be locally and cubically convergent. Additionally, the modified normalized Newton method (MNNM), which converges to symmetric tensors Z-eigenpairs under the same

γ $$ \gamma $$

-Newton stability requirement, is extended by the NNGEM technique. Using a Gröbner basis, a polynomial system solver (NSolve) generates all of the real eigenvalues for us. To illustrate the efficacy of our methodology, we present a few numerical findings.

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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.