Geometric aspects of the theory of Krylov subspace methods

Michael Eiermann; Oliver G. Ernst

doi:10.1017/S0962492901000046

Abstract

The development of Krylov subspace methods for the solution of operator equations has shown that two basic construction principles underlie the most commonly used algorithms: the orthogonal residual (OR) and minimal residual (MR) approaches. It is shown that these can both be formulated as techniques for solving an approximation problem on a sequence of nested subspaces of a Hilbert space, an abstract problem not necessarily related to an operator equation. Essentially all Krylov subspace algorithms result when these subspaces form a Krylov sequence. The well-known relations among the iterates and residuals of MR/OR pairs are shown to hold also in this rather general setting. We further show that a common error analysis for these methods involving the canonical angles between subspaces allows many of the known residual and error bounds to be derived in a simple and consistent manner. An application of this analysis to compact perturbations of the identity shows that MR/OR pairs of Krylov subspace methods converge q-superlinearly when applied to such operator equations.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Eiermann, Michael Ernst, Oliver G. and Schneider, Olaf 2000. Analysis of acceleration strategies for restarted minimal residual methods. Journal of Computational and Applied Mathematics, Vol. 123, Issue. 1-2, p. 261.

Stathopoulos, Andreas 2002. A Case for a Biorthogonal Jacobi--Davidson Method: Restarting and Correction Equation. SIAM Journal on Matrix Analysis and Applications, Vol. 24, Issue. 1, p. 238.

Zavorin, Ilya O’Leary, DianneP and Elman, Howard 2003. Complete stagnation of gmres. Linear Algebra and its Applications, Vol. 367, Issue. , p. 165.

Shen, Yuming and Zhao, Jinxi 2003. Analysis of peaks and plateaus in a Galerkin/minimal residual pair of methods for solving Ax=b. Applied Mathematics and Computation, Vol. 144, Issue. 2-3, p. 441.

Křížek, Michal and Korotov, Sergey 2004. Conjugate Gradient Algorithms and Finite Element Methods. p. 25.

Dauxois, J Nkiet, G.M and Romain, Y 2004. Canonical analysis relative to a closed subspace. Linear Algebra and its Applications, Vol. 388, Issue. , p. 119.

Liesen, Jörg and Tichý, Petr 2004. Convergence analysis of Krylov subspace methods. GAMM-Mitteilungen, Vol. 27, Issue. 2, p. 153.

Beckermann, Bernhard 2005. Image numérique, GMRES et polynômes de Faber. Comptes Rendus. Mathématique, Vol. 340, Issue. 11, p. 855.

Baker, A. H. Jessup, E. R. and Manteuffel, T. 2005. A Technique for Accelerating the Convergence of Restarted GMRES. SIAM Journal on Matrix Analysis and Applications, Vol. 26, Issue. 4, p. 962.

Beckermann, B. Goreinov, S. A. and Tyrtyshnikov, E. E. 2005. Some Remarks on the Elman Estimate for GMRES. SIAM Journal on Matrix Analysis and Applications, Vol. 27, Issue. 3, p. 772.

Szyld, Daniel B. 2006. The many proofs of an identity on the norm of oblique projections. Numerical Algorithms, Vol. 42, Issue. 3-4, p. 309.

García-Archilla, Bosco Sánchez, Juan and Simó, Carles 2006. Krylov methods and determinants for detecting bifurcations in one parameter dependent partial differential equations. BIT Numerical Mathematics, Vol. 46, Issue. 4, p. 731.

Sarkis, Marcus and Szyld, Daniel B. 2007. Optimal left and right additive Schwarz preconditioning for minimal residual methods with Euclidean and energy norms. Computer Methods in Applied Mechanics and Engineering, Vol. 196, Issue. 8, p. 1612.

Zemke, Jens-Peter M. 2007. Abstract perturbed Krylov methods. Linear Algebra and its Applications, Vol. 424, Issue. 2-3, p. 405.

Simoncini, Valeria and Szyld, Daniel B. 2007. Recent computational developments in Krylov subspace methods for linear systems. Numerical Linear Algebra with Applications, Vol. 14, Issue. 1, p. 1.

Simoncini, Valeria and Szyld, Daniel B. 2008. New conditions for non-stagnation of minimal residual methods. Numerische Mathematik, Vol. 109, Issue. 3, p. 477.

Zítko, Jan 2008. How residual bounds for restarted GMRES describe the real behaviour. PAMM, Vol. 8, Issue. 1, p. 10837.

Jiránek, Pavel Rozložník, Miroslav and Gutknecht, Martin H. 2009. How to Make Simpler GMRES and GCR More Stable. SIAM Journal on Matrix Analysis and Applications, Vol. 30, Issue. 4, p. 1483.

Jing, Yan-Fei Huang, Ting-Zhu Zhang, Yong Li, Liang Cheng, Guang-Hui Ren, Zhi-Gang Duan, Yong Sogabe, Tomohiro and Carpentieri, Bruno 2009. Lanczos-type variants of the COCR method for complex nonsymmetric linear systems. Journal of Computational Physics, Vol. 228, Issue. 17, p. 6376.

Strakoš, Zdeněk 2009. Model reduction using the Vorobyev moment problem. Numerical Algorithms, Vol. 51, Issue. 3, p. 363.

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Geometric aspects of the theory of Krylov subspace methods

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