Error bounds for approximate deflating subspaces for linear response eigenvalue problems

Abstract In the linear response eigenvalue problem arising from computational quantum chemistry and physics, one needs to compute a few of smallest positive eigenvalues together with the corresponding eigenvectors. For such a task, most of efficient algorithms are based on an important notion that is the so-called pair of deflating subspaces. If a pair of deflating subspaces is at hand, the computed approximated eigenvalues are partial eigenvalues of the linear response eigenvalue problem. In the case the pair of deflating subspaces is not available, only approximate one, in a recent paper [SIAM J. Matrix Anal. Appl., 35(2), pp.765-782, 2014], Zhang, Xue and Li obtained the relationships between the accuracy in eigenvalue approximations and the distances from the exact deflating subspaces to their approximate ones. In this paper, we establish majorization type results for these relationships. From our majorization results, various bounds are readily available to estimate how accurate the approximate eigenvalues based on information on the approximate accuracy of a pair of approximate deflating subspaces. These results will provide theoretical foundations for assessing the relative performance of certain iterative methods in the linear response eigenvalue problem.

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Weighted Block Golub-Kahan-Lanczos Algorithms for Linear Response Eigenvalue Problem

Mathematics ◽

10.3390/math7010053 ◽

2019 ◽

Vol 7 (1) ◽

pp. 53 ◽

Cited By ~ 1

Author(s):

Hongxiu Zhong ◽

Zhongming Teng ◽

Guoliang Chen

Keyword(s):

Eigenvalue Problem ◽

Error Bounds ◽

Linear Response ◽

Numerical Instability ◽

Lanczos Algorithm ◽

Numerical Examples ◽

Block Algorithm ◽

Restart Strategy ◽

New Algorithms

In order to solve all or some eigenvalues lied in a cluster, we propose a weighted block Golub-Kahan-Lanczos algorithm for the linear response eigenvalue problem. Error bounds of the approximations to an eigenvalue cluster, as well as their corresponding eigenspace, are established and show the advantages. A practical thick-restart strategy is applied to the block algorithm to eliminate the increasing computational and memory costs, and the numerical instability. Numerical examples illustrate the effectiveness of our new algorithms.

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Trace minimization method via penalty for linear response eigenvalue problems

Journal of Industrial and Management Optimization ◽

10.3934/jimo.2021206 ◽

2021 ◽

Vol 0 (0) ◽

pp. 0

Author(s):

Yadan Chen ◽

Yuan Shen ◽

Shanshan Liu

Keyword(s):

Eigenvalue Problem ◽

Linear Response ◽

Large Scale ◽

Eigenvalue Problems ◽

Minimum Principle ◽

Gradient Descent Method ◽

Step Size ◽

Minimization Method ◽

Energy Excitation ◽

Orthogonality Constraint

<p style='text-indent:20px;'>In various applications, such as the computation of energy excitation states of electrons and molecules, and the analysis of interstellar clouds, the linear response eigenvalue problem, which is a special type of the Hamiltonian eigenvalue problem, is frequently encountered. However, traditional eigensolvers may not be applicable to this problem owing to its inherently large scale. In fact, we are usually more interested in computing some of the smallest positive eigenvalues. To this end, a trace minimum principle optimization model with orthogonality constraint has been proposed. On this basis, we propose an unconstrained surrogate model called trace minimization via penalty, and we establish its equivalence with the original constrained model, provided that the penalty parameter is larger than a certain threshold. By avoiding the orthogonality constraint, we can use a gradient-type method to solve this model. Specifically, we use the gradient descent method with Barzilai–Borwein step size. Moreover, we develop a restarting strategy for the proposed algorithm whereby higher accuracy and faster convergence can be achieved. This is verified by preliminary experimental results.</p>

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Approximation of Eigenvalues of Sturm-Liouville Problems by Using Hermite Interpolation

Abstract and Applied Analysis ◽

10.1155/2013/412028 ◽

2013 ◽

Vol 2013 ◽

pp. 1-14 ◽

Cited By ~ 1

Author(s):

M. M. Tharwat ◽

S. M. Al-Harbi

Keyword(s):

Boundary Conditions ◽

Error Bounds ◽

Eigenvalue Problems ◽

Sampling Theorem ◽

Eigenvalue Parameter ◽

Derivative Sampling ◽

Sturm Liouville ◽

Truncation And Amplitude Errors ◽

Computable Error Bounds ◽

Hermite Interpolations

Eigenvalue problems with eigenparameter appearing in the boundary conditions usually have complicated characteristic determinant where zeros cannot be explicitly computed. In this paper, we use the derivative sampling theorem “Hermite interpolations” to compute approximate values of the eigenvalues of Sturm-Liouville problems with eigenvalue parameter in one or two boundary conditions. We use recently derived estimates for the truncation and amplitude errors to compute error bounds. Also, using computable error bounds, we obtain eigenvalue enclosures. Also numerical examples, which are given at the end of the paper, give comparisons with the classical sinc method and explain that the Hermite interpolations method gives remarkably better results.

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On error bounds in strong approximations for eigenvalue problems

The Journal of the Australian Mathematical Society Series B Applied Mathematics ◽

10.1017/s0334270000002629 ◽

1981 ◽

Vol 22 (3) ◽

pp. 270-283 ◽

Cited By ~ 2

Author(s):

R. P. Kulkarani ◽

B. V. Limaye

Keyword(s):

Numerical Experiment ◽

Galerkin Method ◽

Error Bounds ◽

Strong Approximation ◽

Eigenvalue Problems ◽

Strong Approximations ◽

Asymptotic Case ◽

The Galerkin Method

AbstractSome corrections of error bounds obtained by Chatelin and Lemordant for the first three terms of the asymptotic case of a strong approximation are given. The error bounds for the approximations of order 2 in the Galerkin method are compared with the Rayleigh quotients constructed with the eigenvectors in the Sloan method. A numerical experiment is also carried out.

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