Enlarged GMRES for solving linear systems with one or multiple right-hand sides

Abstract We propose a variant of the generalized minimal residual (GMRES) method for solving linear systems of equations with one or multiple right-hand sides. Our method is based on the idea of the enlarged Krylov subspace to reduce communication. It can be interpreted as a block GMRES method. Hence, we are interested in detecting inexact breakdowns. We introduce a strategy to perform the test of detection. Furthermore, we propose a technique for deflating eigenvalues that has two benefits. The first advantage is to avoid the plateau of convergence after the end of a cycle in the restarted version. The second is to have very fast convergence when solving the same system with different right-hand sides, each given at a different time (useful in the context of a constrained pressure residual preconditioner). We test our method with these deflation techniques on academic test matrices arising from solving linear elasticity and convection–diffusion problems as well as matrices arising from two real-life applications, seismic imaging and simulations of reservoirs. With the same memory cost we obtain a saving of up to $50 \%$ in the number of iterations required to reach convergence with respect to the original method.

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Recycling Krylov Subspaces and Truncating Deflation Subspaces for Solving Sequence of Linear Systems

ACM Transactions on Mathematical Software ◽

10.1145/3439746 ◽

2021 ◽

Vol 47 (2) ◽

pp. 1-30

Author(s):

Hussam Al Daas ◽

Laura Grigori ◽

Pascal Hénon ◽

Philippe Ricoux

Keyword(s):

Linear Systems ◽

Krylov Subspace ◽

Real Life ◽

Krylov Subspace Methods ◽

Krylov Subspaces ◽

Systems Of Equations ◽

The Matrix ◽

Value Decomposition ◽

The Impact ◽

Linear Systems Of Equations

This article presents deflation strategies related to recycling Krylov subspace methods for solving one or a sequence of linear systems of equations. Besides well-known strategies of deflation, Ritz-, and harmonic Ritz-based deflation, we introduce an Singular Value Decomposition based deflation technique. We consider the recycling in two contexts: recycling the Krylov subspace between the restart cycles and recycling a deflation subspace when the matrix changes in a sequence of linear systems. Numerical experiments on real-life reservoir simulation demonstrate the impact of our proposed strategy.

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A block GMRES method with deflated restarting for solving linear systems with multiple shifts and multiple right-hand sides

Numerical Linear Algebra with Applications ◽

10.1002/nla.2148 ◽

2018 ◽

Vol 25 (5) ◽

pp. e2148 ◽

Cited By ~ 9

Author(s):

Dong-Lin Sun ◽

Ting-Zhu Huang ◽

Yan-Fei Jing ◽

Bruno Carpentieri

Keyword(s):

Linear Systems ◽

Gmres Method ◽

Right Hand ◽

Deflated Restarting

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A Polynomial Preconditioned Global CMRH Method for Linear Systems with Multiple Right-Hand Sides

Journal of Applied Mathematics ◽

10.1155/2013/457089 ◽

2013 ◽

Vol 2013 ◽

pp. 1-7 ◽

Cited By ~ 1

Author(s):

Ke Zhang ◽

Chuanqing Gu

Keyword(s):

Theoretical Result ◽

Linear Systems ◽

Numerical Experiments ◽

Krylov Subspace ◽

Polynomial Degree ◽

Right Hand

The restarted global CMRH method (Gl-CMRH(m)) (Heyouni, 2001) is an attractive method for linear systems with multiple right-hand sides. However, Gl-CMRH(m) may converge slowly or even stagnate due to a limited Krylov subspace. To ameliorate this drawback, a polynomial preconditioned variant of Gl-CMRH(m) is presented. We give a theoretical result for the square case that assures that the number of restarts can be reduced with increasing values of the polynomial degree. Numerical experiments from real applications are used to validate the effectiveness of the proposed method.

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Folded Preconditioner: A New Class of Preconditioners for Krylov Subspace Methods to Solve Redundancy-Reduced Linear Systems of Equations

IEEE Transactions on Magnetics ◽

10.1109/tmag.2009.2014156 ◽

2009 ◽

Vol 45 (5) ◽

pp. 2068-2075 ◽

Cited By ~ 8

Author(s):

T. Mifune ◽

Y. Takahashi ◽

T. Iwashita

Keyword(s):

Linear Systems ◽

Krylov Subspace ◽

Krylov Subspace Methods ◽

Systems Of Equations ◽

Subspace Methods ◽

New Class ◽

Linear Systems Of Equations

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Some Hyperbolic Iterative Methods for Linear Systems

Journal of Applied Mathematics ◽

10.1155/2020/9874162 ◽

2020 ◽

Vol 2020 ◽

pp. 1-8 ◽

Cited By ~ 1

Author(s):

K. Niazi Asil ◽

M. Ghasemi Kamalvand

Keyword(s):

Linear Systems ◽

Iterative Methods ◽

Krylov Subspace ◽

Polarized Light ◽

Inner Product ◽

Systems Of Equations ◽

Theory Of Relativity ◽

Indefinite Inner Product ◽

Special Case ◽

Linear Systems Of Equations

The indefinite inner product defined by J=diagj1,…,jn, jk∈−1,+1, arises frequently in some applications, such as the theory of relativity and the research of the polarized light. This indefinite scalar product is referred to as hyperbolic inner product. In this paper, we introduce three indefinite iterative methods: indefinite Arnoldi’s method, indefinite Lanczos method (ILM), and indefinite full orthogonalization method (IFOM). The indefinite Arnoldi’s method is introduced as a process that constructs a J-orthonormal basis for the nondegenerated Krylov subspace. The ILM method is introduced as a special case of the indefinite Arnoldi’s method for J-Hermitian matrices. IFOM is mentioned as a process for solving linear systems of equations with J-Hermitian coefficient matrices. Finally, by providing numerical examples, the FOM, IFOM, and ILM processes have been compared with each other in terms of the required time for solving linear systems and also from the point of the number of iterations.

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