The Anderson Model of Localization: A Challenge for Modern Eigenvalue Methods

Elsner, Ulrich, Mehrmann, Volker, Römer, Rudolf A., Schreiber, Michael

09 September 2005

We present a comparative study of the application of modern eigenvalue algorithms to an eigenvalue problem arising in quantum physics, namely, the computation of a few interior eigenvalues and their associated eigenvectors for the large, sparse, real, symmetric, and indefinite matrices of the Anderson model of localization. We compare the Lanczos algorithm in the 1987 implementation of Cullum and Willoughby with the implicitly restarted Arnoldi method coupled with polynomial and several shift-and-invert convergence accelerators as well as with a sparse hybrid tridiagonalization method. We demonstrate that for our problem the Lanczos implementation is faster and more memory efficient than the other approaches. This seemingly innocuous problem presents a major challenge for all modern eigenvalue algorithms.

Anderson model of localization

Arnoldi algorithm

polynomial convergence accelerators

ddc:510

Eigenwertproblem

Lanczos-Algorithmus

Lagrangian invariant subspaces of Hamiltonian matrices

Mehrmann, Volker, Xu, Hongguo

14 September 2005

The existence and uniqueness of Lagrangian invariant subspaces of Hamiltonian matrices is studied. Necessary and sufficient conditions are given in terms of the Jordan structure and certain sign characteristics that give uniqueness of these subspaces even in the presence of purely imaginary eigenvalues. These results are applied to obtain in special cases existence and uniqueness results for Hermitian solutions of continuous time algebraic Riccati equations.

Hamiltonian matrix

Lagrangian invariant subspace

ddc:510

Algebraische Riccati-Gleichung

Eigenwertproblem

Symplektische Matrix

Preconditioned iterative methods for monotone nonlinear eigenvalue problems

Solov'ëv, Sergey I.

11 April 2006

This paper proposes new iterative methods for the efficient computation of the smallest eigenvalue of the symmetric nonlinear matrix eigenvalue problems of large order with a monotone dependence on the spectral parameter. Monotone nonlinear eigenvalue problems for differential equations have important applications in mechanics and physics. The discretization of these eigenvalue problems leads to ill-conditioned nonlinear eigenvalue problems with very large sparse matrices monotone depending on the spectral parameter. To compute the smallest eigenvalue of large matrix nonlinear eigenvalue problem, we suggest preconditioned iterative methods: preconditioned simple iteration method, preconditioned steepest descent method, and preconditioned conjugate gradient method. These methods use only matrix-vector multiplications, preconditioner-vector multiplications, linear operations with vectors and inner products of vectors. We investigate the convergence and derive grid-independent error estimates of these methods for computing eigenvalues. Numerical experiments demonstrate practical effectiveness of the proposed methods for a class of mechanical problems.

conjugate gradient method

preconditioning

steepest descent method

ddc:510

Iterativ

Nichtlineares Eigenwertproblem

Hamiltonian eigenvalue symmetry for quadratic operator eigenvalue problems

Pester, Cornelia

01 September 2006

When the eigenvalues of a given eigenvalue problem are symmetric with respect to the real and the imaginary axes, we speak about a Hamiltonian eigenvalue symmetry or a Hamiltonian structure of the spectrum. This property can be exploited for an efficient computation of the eigenvalues. For some elliptic boundary value problems it is known that the derived eigenvalue problems have this Hamiltonian symmetry. Without having a specific application in mind, we trace the question, under which assumptions the spectrum of a given quadratic eigenvalue problem possesses the Hamiltonian structure.

Hamiltonian eigenvalue symmetry

operator pencil

ddc:510

Nichtlineares Eigenwertproblem

Operatorbüschel

Spektraltheorie

The Laplace and the linear elasticity problems near polyhedral corners and associated eigenvalue problems

Meyer, Arnd, Pester, Cornelia

01 September 2006

The solutions to certain elliptic boundary value problems have singularities with a typical structure near polyhedral corners. This structure can be exploited to devise an eigenvalue problem whose solution can be used to quantify the singularities of the given boundary value problem. It is necessary to parametrize a ball centered at the corner. There are different possibilities for a suitable parametrization; from the numerical point of view, spherical coordinates are not necessarily the best choice. This is why we do not specify a parametrization in this paper but present all results in a rather general form. We derive the eigenvalue problems that are associated with the Laplace and the linear elasticity problems and show interesting spectral properties. Finally, we discuss the necessity of widely accepted symmetry properties of the elasticity tensor. We show in an example that some of these properties are not only dispensable, but even invalid, although claimed in many standard books on linear elasticity.

corner singularities

linear elasticity problem

ddc:510

Eckensingularität

Eigenwertproblem

Elliptisches Randwertproblem

Laplace-Beltrami-Operator

On the Convergence Factor in Multilevel Methods for Solving 3D Elasticity Problems

Jung, Michael, Todorov, Todor D.

01 September 2006

The constant gamma in the strengthened Cauchy-Bunyakowskii-Schwarz inequality is a basic tool for constructing of two-level and multilevel preconditioning matrices. Therefore many authors consider estimates or computations of this quantity. In this paper the bilinear form arising from 3D linear elasticity problems is considered on a polyhedron. The cosine of the abstract angle between multilevel finite element subspaces is computed by a spectral analysis of a general eigenvalue problem. Octasection and bisection approaches are used for refining the triangulations. Tetrahedron, pentahedron and hexahedron meshes are considered. The dependence of the constant $\gamma$ on the Poisson ratio is presented graphically.

linear elasticity problem

ddc:510

Eigenwertproblem

Finite-Elemente-Methode

Mehrgitterverfahren

A residual a posteriori error estimator for the eigenvalue problem for the Laplace-Beltrami operator

Pester, Cornelia

06 September 2006

The Laplace-Beltrami operator corresponds to the Laplace operator on curved surfaces. In this paper, we consider an eigenvalue problem for the Laplace-Beltrami operator on subdomains of the unit sphere in $\R^3$. We develop a residual a posteriori error estimator for the eigenpairs and derive a reliable estimate for the eigenvalues. A global parametrization of the spherical domains and a carefully chosen finite element discretization allows us to use an approach similar to the one for the two-dimensional case. In order to assure results in the quality of those for plane domains, weighted norms and an adapted Clément-type interpolation operator have to be introduced.

Clément-type interpolation

spherical domains

ddc:510

A-posteriori-Abschätzung

Eigenwertproblem

Laplace-Beltrami-Operator

Eigenvibrations of a plate with elastically attached load

Solov'ëv, Sergey I.

11 April 2006

This paper is concerned with the investigation of the nonlinear eigenvalue problem describing the natural oscillations of a plate with a load that elastically attached to it. We study properties of eigenvalues and eigenfunctions of this eigenvalue problem and prove the existence theorem for eigensolutions. Theoretical results are illustrated by numerical experiments.

info:eu-repo/classification/ddc/510

ddc:510

natural oscillations, plate

Hamiltonian eigenvalue symmetry for quadratic operator eigenvalue problems

Pester, Cornelia

01 September 2006

When the eigenvalues of a given eigenvalue problem are symmetric with respect to the real and the imaginary axes, we speak about a Hamiltonian eigenvalue symmetry or a Hamiltonian structure of the spectrum. This property can be exploited for an efficient computation of the eigenvalues. For some elliptic boundary value problems it is known that the derived eigenvalue problems have this Hamiltonian symmetry. Without having a specific application in mind, we trace the question, under which assumptions the spectrum of a given quadratic eigenvalue problem possesses the Hamiltonian structure.

info:eu-repo/classification/ddc/510

ddc:510

Existence of the guided modes of an optical fiber

Solov'ëv, Sergey I.

11 April 2006

The present paper is devoted to the investigation of the guided wave problem. This problem is formulated as the eigenvalue problem with a compact self-adjoint operator pencil. Applying the minimax principle for the compact operators in the Hilbert space we obtain a necessary and sufficient condition for the existence of a preassigned number of linearly independent guided modes. As a consequence of this result we also derive simple sufficient conditions, which can be easily applied in practice. We give a statement of the problem in a bounded domain and propose an efficient method for solving the problem.

info:eu-repo/classification/ddc/510

ddc:510

guided modes, optical fiber