The quasi-Newton least squares method: A new and fast secant method analyzed for linear systems

Rob Haelterman; Joris Degroote; Dirk Van Heule; Jan Vierendeels

doi:10.1137/070710469

The quasi-Newton least squares method: A new and fast secant method analyzed for linear systems

Rob Haelterman, Joris Degroote, Dirk Van Heule, Jan Vierendeels

University of Ghent

Research output: Contribution to journal › Article › peer-review

Abstract

We present a new quasi-Newton method that can solve systems of equations of which no information is known explicitly and which requires no special structure of the system matrix, like positive definiteness or sparseness. The method builds an approximate Jacobian based on input-output combinations of a black box system, uses a rank-one update of this Jacobian after each iteration, and satisfies the secant equation. While it has originally been developed for nonlinear equations we analyze its properties and performance when applied to linear systems. Analytically, the method is shown to be convergent in n + 1 iterations (n being the number of unknowns), irrespective of the nature of the system matrix. The performance of this method is greatly superior to other quasi-Newton methods and comparable with GMRes when tested on a number of standardized test-cases.

Original language	English
Pages (from-to)	2347-2368
Number of pages	22
Journal	SIAM Journal on Numerical Analysis
Volume	47
Issue number	3
DOIs	https://doi.org/10.1137/070710469
Publication status	Published - 2009

Keywords

GMRes
Iterative method
Least squares
Linear algebra
Quasi-Newton method
Rank-one update
Secant method

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10.1137/070710469

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title = "The quasi-Newton least squares method: A new and fast secant method analyzed for linear systems",

abstract = "We present a new quasi-Newton method that can solve systems of equations of which no information is known explicitly and which requires no special structure of the system matrix, like positive definiteness or sparseness. The method builds an approximate Jacobian based on input-output combinations of a black box system, uses a rank-one update of this Jacobian after each iteration, and satisfies the secant equation. While it has originally been developed for nonlinear equations we analyze its properties and performance when applied to linear systems. Analytically, the method is shown to be convergent in n + 1 iterations (n being the number of unknowns), irrespective of the nature of the system matrix. The performance of this method is greatly superior to other quasi-Newton methods and comparable with GMRes when tested on a number of standardized test-cases.",

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author = "Rob Haelterman and Joris Degroote and \{Van Heule\}, Dirk and Jan Vierendeels",

year = "2009",

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AU - Haelterman, Rob

AU - Degroote, Joris

AU - Van Heule, Dirk

AU - Vierendeels, Jan

PY - 2009

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N2 - We present a new quasi-Newton method that can solve systems of equations of which no information is known explicitly and which requires no special structure of the system matrix, like positive definiteness or sparseness. The method builds an approximate Jacobian based on input-output combinations of a black box system, uses a rank-one update of this Jacobian after each iteration, and satisfies the secant equation. While it has originally been developed for nonlinear equations we analyze its properties and performance when applied to linear systems. Analytically, the method is shown to be convergent in n + 1 iterations (n being the number of unknowns), irrespective of the nature of the system matrix. The performance of this method is greatly superior to other quasi-Newton methods and comparable with GMRes when tested on a number of standardized test-cases.

AB - We present a new quasi-Newton method that can solve systems of equations of which no information is known explicitly and which requires no special structure of the system matrix, like positive definiteness or sparseness. The method builds an approximate Jacobian based on input-output combinations of a black box system, uses a rank-one update of this Jacobian after each iteration, and satisfies the secant equation. While it has originally been developed for nonlinear equations we analyze its properties and performance when applied to linear systems. Analytically, the method is shown to be convergent in n + 1 iterations (n being the number of unknowns), irrespective of the nature of the system matrix. The performance of this method is greatly superior to other quasi-Newton methods and comparable with GMRes when tested on a number of standardized test-cases.

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KW - Iterative method

KW - Least squares

KW - Linear algebra

KW - Quasi-Newton method

KW - Rank-one update

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JO - SIAM Journal on Numerical Analysis

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The quasi-Newton least squares method: A new and fast secant method analyzed for linear systems

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Keywords

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