Preconditioned Iterative Methods for Solving Linear Least Squares Problems

Bru, Rafael; Marı́n, José; Mas, José; Tůma, Miroslav

doi:10.1137/130931588

Cited by 19 publications

(18 citation statements)

References 55 publications

(87 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Introduction. In recent years, a number of methods have been proposed for preconditioning sparse linear least-squares problems; a brief overview with a comprehensive list of references is included in the introduction to the paper of Bru et al [4]. The recent study of Gould and Scott [20,21] reviewed many of these methods (specifically those for which software has been made available) and then tested and compared their performance using a range of examples coming from practical applications.…”

mentioning

confidence: 99%

On Using Cholesky-Based Factorizations and Regularization for Solving Rank-Deficient Sparse Linear Least-Squares Problems

Scott¹

2017

SIAM J. Sci. Comput.

View full text Add to dashboard Cite

Abstract. By examining the performance of modern parallel sparse direct solvers and exploiting our knowledge of the algorithms behind them, we perform numerical experiments to study how they can be used to efficiently solve rank-deficient sparse linear least-squares problems arising from practical applications. The Cholesky factorization of the normal equations breaks down when the least-squares problem is rank-deficient, while applying a symmetric indefinite solver to the augmented system can give an unacceptable level of fill in the factors. To try to resolve these difficulties, we consider a regularization procedure that modifies the diagonal of the unregularized matrix. This leads to matrices that are easier to factorize. We consider both the regularized normal equations and the regularized augmented system. We employ the computed factors of the regularized systems as preconditioners with an iterative solver to obtain the solution of the original (unregularized) problem. Furthermore, we look at using limited-memory incomplete Cholesky-based factorizations and how these can offer the potential to solve very large problems.Key words. least-squares problems, normal equations, augmented system, sparse matrices, direct methods, iterative methods, Cholesky factorizations, preconditioning, regularization AMS subject classifications. 65F05, 65F50 DOI. 10.1137/16M10653801. Introduction. In recent years, a number of methods have been proposed for preconditioning sparse linear least-squares problems; a brief overview with a comprehensive list of references is included in the introduction to the paper of Bru et al. [4]. The recent study of Gould and Scott [20,21] reviewed many of these methods (specifically those for which software has been made available) and then tested and compared their performance using a range of examples coming from practical applications. One of the outcomes of that study was some insight into which least-squares problems in the widely used sparse matrix collections CUTEst [19] and University of Florida [10] currently pose a real challenge for direct methods and/or iterative solvers. In particular, the study found that most of the available software packages were not reliable or efficient for rank-deficient least-squares problems (at least not when run with the recommended settings for the input parameters that were employed in the study). In this paper, we look further at such problems and focus on the effectiveness of both sparse direct solvers and iterative methods with incomplete factorization preconditioners. A key theme is the use of regularization (see, for example, [15,48,49]). We propose computing a factorization (either complete or incomplete) of a regularized problem and then using this as a preconditioner for an iterative solver to recover the solution of the original (unregularized) problem.The problem we are interested in is

show abstract

mentioning

confidence: 99%

On Using Cholesky-Based Factorizations and Regularization for Solving Rank-Deficient Sparse Linear Least-Squares Problems

Scott¹

2017

SIAM J. Sci. Comput.

View full text Add to dashboard Cite

show abstract

“…Since A T A is much denser than A, to get a sparse preconditioner a lot of entries should be dropped, and some instabilities may appear. To prevent this possibility two additional strategies are used in [11] to improve robustness. The first one is to replace the way that the pivots are computed.…”

Section: Bif For Least Squares Problemsmentioning

confidence: 99%

“…Instead of to compute them as in (10), that is as sr i , they are computed as z T i A T Az i . The second one follows the ideas of Tismenetsky in [18], by storing additional entries that are used only in computations, but finally discarded a better preconditioner is computed, see Algorithm 2.2 in [11]. We refer to this preconditioner as lsBIF.…”

Section: Bif For Least Squares Problemsmentioning

confidence: 99%

“…In [11] lsBIF was compared with IC, an incomplete Cholesky factorization preconditioner see [4] for implementation details; AINV; and Cholesky incomplete modified Gram Schmidt, CIMGS [19], see [15] for details of the implementation. All preconditioners were used to accelerate the conjugate gradient for least squares (CGLS) [5] iterative method.…”

Section: Bif For Least Squares Problemsmentioning

confidence: 99%

See 1 more Smart Citation

Preconditioners based on the ISM factorization

Bru

Cerdán

Marı́n

et al. 2015

Analele Universitatii "Ovidius" Constanta - Seria Matematica

Self Cite

View full text Add to dashboard Cite

show abstract

“…The main contribution of this paper is that we propose a real Jacobian-free preconditioner construction technique for solving nonlinear least square problems. Compared with other existing preconditioning techniques [1,3,5,35], our method requires neither the computation of the Jacobian matrix in any iteration step, the sparsity or special structure of the Jacobian matrix, nor the subroutine for the gradient computation [19]. It only requires the objective function F(x) and subroutines to compute J (x k )v and J (x k ) T w. In other words, our implicit preconditioner construction can be used to determine preconditioners for all these existing Jacobian-free methods for nonlinear equations and NLS problems.…”

Section: Introductionmentioning

confidence: 99%

Jacobian-Free Implicit Inner-Iteration Preconditioner for Nonlinear Least Squares Problems

Zheng

Hayami

2016

J Sci Comput

View full text Add to dashboard Cite

Nonlinear least squares (NLS) problems arise in many applications. The common solvers require to compute and store the corresponding Jacobian matrix explicitly, which is too expensive for large problems. Recently, some Jacobian-free (or matrix free) methods were proposed, but most of these methods are not really Jacobian free since the full or partial Jacobian matrix still needs to be computed in some iteration steps. In this paper, we propose an effective real Jacobian free method especially for large NLS problems, which is realized by the novel combination of using automatic differentiation for J (x)v and J (x) T v along with the implicit iterative preconditioning ideas. Together, they yield a new and effective three-level iterative approach. In the outer level, the dogleg/trust region method is employed to solve the NLS problem. At each iteration of the dogleg method, we adopt the iterative linear least squares (LLS) solvers, CGLS or BA-GMRES method, to solve the LLS problem generated at each step of the dogleg method as the middle iteration. In order to accelerate the convergence of the iterative LLS solver, we propose an implicit inner iteration preconditioner based on the weighted Jacobi method. Compared to the existing Jacobian-free methods, our proposed three-level method need not compute any part of the Jacobian matrix explicitly in 123 J Sci Comput any iteration step. Furthermore, our method does not rely on the sparsity or structure pattern of the Jacobian, gradient or Hessian matrix. In other words, our method also works well for dense Jacobian matrices. Numerical experiments show the superiority of our proposed method.

show abstract

Preconditioned Iterative Methods for Solving Linear Least Squares Problems

Cited by 19 publications

References 55 publications

On Using Cholesky-Based Factorizations and Regularization for Solving Rank-Deficient Sparse Linear Least-Squares Problems

On Using Cholesky-Based Factorizations and Regularization for Solving Rank-Deficient Sparse Linear Least-Squares Problems

Preconditioners based on the ISM factorization

Jacobian-Free Implicit Inner-Iteration Preconditioner for Nonlinear Least Squares Problems

Contact Info

Product

Resources

About