Structured Factorizations in Scalar Product Spaces

Mackey, D. Steven; Mackey, Niloufer; Tisseur, Françoise

doi:10.1137/040619363

Cited by 66 publications

(63 citation statements)

References 44 publications

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“…Eigenvalues of J-unitary and J-Hermitian matrices have well researched properties, nicely presented in [16,Section 7] with J-unitary matrices being referred to as members of the automorphism group G and J-Hermitian matrices being referred to as members of the Jordan algebra J. These results apply for various scalar products, but when it comes to hyperbolic products and a hyperbolic Schur decomposition, more can be said about the atomic blocks in T .…”

Section: Proposition 44 (J-normal Matrices) If a Matrix A Has A Hypmentioning

confidence: 95%

“…Here, we see that λ ∈ R (which also follows straight from [16,Theorem 7.6]) and α = α, i.e., α is real, so […”

Section: Proposition 44 (J-normal Matrices) If a Matrix A Has A Hypmentioning

confidence: 99%

“…Trivially, this means that all blocks T k of order 1 are real. Notice that if T k of order 2 has non-real eigenvalues λ 2 , due to [16,Theorem 7.6], so their partial multiplicity must be 1. If they are real, their partial multiplicity is 1 or 2, depending on the diagonalizability of T k .…”

Section: Existence Of the Hyperbolic Schur Decomposition For J -Hermimentioning

confidence: 99%

“…It is used, for example, in the theory of relativity and in the research of the polarized light. More on the applications of such products can be found in [10,13,14,17].The Euclidean matrix decompositions have some nice structure preserving properties even in nonstandard scalar products, as shown by Mackey, Mackey and Tisseur [16], but it is often worth looking into versions of such decompositions that respect the structures related with the given scalar product. There is plenty of research on the subject, i.e., hyperbolic SVD [17,24], J 1 J 2 -SVD [9], two-sided hyperbolic SVD [20], hyperbolic CS decomposition [8,10] and indefinite QR factorization [19].…”

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The hyperbolic Schur decomposition

Šego

2014

Linear Algebra and its Applications

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We propose a hyperbolic counterpart of the Schur decomposition, with the emphasis on the preservation of structures related to some given hyperbolic scalar product. We give results regarding the existence of such a decomposition and research the properties of its block triangular factor for various structured matrices.Keywords: indefinite scalar products, hyperbolic scalar products, Schur decomposition, Jordan decomposition, quasitriangularization, quasidiagonalization, structured matrices 2000 MSC: 15A63, 46C20, 65F25 IntroductionThe Schur decomposition A = U T U * , sometimes also called Schur's unitary triangularization, is a unitary similarity between any given square matrix A ∈ C n×n and some upper triangular matrix T ∈ C n×n . Such a decomposition has a structured form for various structured matrices, i.e., T is diagonal if and only if A is normal, real diagonal if and only if A is Hermitian, positive (nonnegative) real diagonal if and only if A is positive (semi)definite and so on.Furthermore, the Schur decomposition can be computed in a numerically stable way, making it a good choice for calculating the eigenvalues of A (which are the diagonal elements of T ) as well as the various matrix functions (for more details, see [11]). Its structure preserving property allows to save time and memory when working with structured matrices. For example, computing the value of some function of a Hermitian matrix is reduced to working with a diagonal matrix, which involves only evaluation of the diagonal elements.Unitary matrices are very useful when working with the traditional Euclidean scalar product x, y = y * x, as their columns form an orthonormal basis of C n . However, many applications require a nonstandard scalar product which is usually defined by [x, y] J = y * Jx, where J is some nonsingular matrix, and many of these applications consider Hermitian or skew-Hermitian J. The hyperbolic Email address: vsego@math.hr (VedranŠego) scalar product defined by a signature matrix J = diag(j 1 , . . . , j n ) (j k ∈ {−1, 1}) arises frequently in applications. It is used, for example, in the theory of relativity and in the research of the polarized light. More on the applications of such products can be found in [10,13,14,17].The Euclidean matrix decompositions have some nice structure preserving properties even in nonstandard scalar products, as shown by Mackey, Mackey and Tisseur [16], but it is often worth looking into versions of such decompositions that respect the structures related with the given scalar product. There is plenty of research on the subject, i.e., hyperbolic SVD [17,24], J 1 J 2 -SVD [9], two-sided hyperbolic SVD [20], hyperbolic CS decomposition [8,10] and indefinite QR factorization [19].There are many advantages of using decompositions related to some specific, nonstandard scalar product, as such decompositions preserve structures related to a given scalar product. They can simplify calculation and provide a better insight into the structures of such structured matrices.In this paper w...

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Section: Proposition 44 (J-normal Matrices) If a Matrix A Has A Hypmentioning

confidence: 95%

“…Here, we see that λ ∈ R (which also follows straight from [16,Theorem 7.6]) and α = α, i.e., α is real, so […”

Section: Proposition 44 (J-normal Matrices) If a Matrix A Has A Hypmentioning

confidence: 99%

Section: Existence Of the Hyperbolic Schur Decomposition For J -Hermimentioning

confidence: 99%

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confidence: 99%

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The hyperbolic Schur decomposition

Šego

2014

Linear Algebra and its Applications

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“…Introduction. Orthosymmetric scalar products, introduced in [9] by Mackey, Mackey and Tisseur, still do not belong to the standard vocabulary of numerical linear algebra, even though they provide a unified setting for many modern structure preserving matrix tools (see for example [2,8,9,10]). …”

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confidence: 99%

Orthosymmetric block rotations

Singer¹

2012

ELA

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Abstract. Rotations are essential transformations in many parts of numerical linear algebra. In this paper, it is shown that there exists a family of matrices unitary with respect to an orthosymmetric scalar product J, that can be decomposed into the product of two J-unitary matrices-a block diagonal matrix and an orthosymmetric block rotation. This decomposition can be used for computing various one-sided and two-sided matrix transformations by divide-and-conquer or treelike algorithms. As an illustration, a blocked version of the QR-like factorization of a given matrix is considered.

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A Padé family of iterations for the matrix sector function and the matrix pth root

Laszkiewicz

Ziętak

2009

Numerical Linear Algebra App

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A family of iterations for the sector function based on the Padé table of a certain hypergeometric function is derived and investigated. This generalizes a result of Kenney and Laub for the sign function and yields a whole family of iterative methods for computing the matrix pth root.It is proved that the iterations for the matrix sector function corresponding to the main diagonal of the Padé table preserve the structure of a group of automorphisms associated with a scalar product.The regions of convergence of the Padé iterations for the matrix sector function are investigated theoretically and experimentally. Certain conjectures formulated on the regions of convergence have been verified in particular cases.

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Structured Factorizations in Scalar Product Spaces

Cited by 66 publications

References 44 publications

The hyperbolic Schur decomposition

The hyperbolic Schur decomposition

Orthosymmetric block rotations

A Padé family of iterations for the matrix sector function and the matrix pth root

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