Skewhermitian and mixed pencils

2014 ◽  
Author(s):  
Leiba Rodman
Keyword(s):  
Hermitian Matrix ◽  
The Other ◽  
Canonical Forms ◽  
Complex Field ◽  
Complex Matrix ◽  
Analogous Property ◽  
Matrix Pencils

This chapter turns to matrix pencils of the form A + tB, where one of the matrices A or B is skewhermitian and the other may be hermitian or skewhermitian. Canonical forms of such matrix pencils are given under strict equivalence and under simultaneous congruence, with full detailed proofs, again based on the Kronecker forms. Comparisons with real and complex matrix pencils are presented. In contrast to hermitian matrix pencils, two complex skewhermitian matrix pencils that are simultaneously congruent under quaternions need not be simultaneously congruent under the complex field, although an analogous property is valid for pencils of real skewsymmetric matrices. Similar results hold for real or complex matrix pencils A + tB, where A is real symmetric or complex hermitian and B is real skewsymmetric or complex skewhermitian.

Appendix: Real and complex canonical forms

2014 ◽  
Author(s):  
Leiba Rodman
Keyword(s):  
Canonical Forms ◽  
Real Matrix ◽  
Complex Matrix ◽  
Complex Matrices ◽  
Matrix Pencils ◽  
Real Matrices

This chapter presents canonical forms for real and complex matrices and for pairs of real and complex matrices, or matrix pencils, with symmetries. All these forms are known, and most are well-known. The chapter first looks at Jordan and Kronecker canonical forms, before turning to real matrix pencils with symmetries. It provides canonical forms for pairs of real matrices, either one of which is symmetric or skewsymmetric, or what is the same, corresponding matrix pencils. Finally, this chapter presents canonical forms of complex matrix pencils with various symmetries, such as complex matrix pencils with symmetries with respect to transposition.

Mixed matrix pencils: Nonstandard involutions

2014 ◽  
Author(s):  
Leiba Rodman
Keyword(s):  
Canonical Form ◽  
The Other ◽  
Canonical Forms ◽  
Quaternion Matrix ◽  
Mixed Matrix ◽  
Quaternion Matrices ◽  
Matrix Pencils

This chapter also studies the canonical forms of mixed quaternion matrix pencils, i.e., such that one of the two matrices is φ‎-hermitian and the other is φ‎-skewhermitian, with respect to simultaneous φ‎-congruence. It starts by formulating the canonical form for φ‎-hsk matrix pencils under strict equivalence. Other canonical forms of mixed matrix pencils are developed with respect to strict equivalence. As an application, this chapter provides canonical forms of quaternion matrices under φ‎-congruence. As in the preceding chapter, this chapter also fixes a nonstandard involution φ‎ throughout and a quaternion β‎(φ‎) such that φ‎=(β‎(φ‎)) = −β‎(φ‎) and ∣β‎(φ‎)∣ = 1.

On an extension of Wallace's pedal property of the circumcircle

1924 ◽  
Vol 22 (1) ◽  
pp. 34-41 ◽  
Author(s):  
H. W. Richmond
Keyword(s):  
Euclidean Space ◽  
The Other ◽  
Analogous Property ◽  
Recent Part

1. Mr J. P. Gabbatt has discussed in the most recent Part of the Proceedingsof this Society the Pedal locus of a simplex in hyperspace. It is, however, possible to regard the pedal property of the circumcircle somewhat differently and so to seek other extensions. Given a circle, any three points on it are vertices of an inscribed triangle, and the feet of the perpendiculars on the sides from any fourth point of the circle are collinear. Is there any curve in space on which an analogous property holds for any five points, viz. that the feet of the perpendiculars from any one upon the faces of the tetrahedron formed by the other four are coplanar?It will be shown that curves of order n exist in Euclidean space of n dimensions on which any n + 2 points have such a property; but that the curves cannot be real if n is odd.

scholarly journals Sign Characteristics of Regular Hermitian Matrix Pencils under Generic Rank-1 and Rank-2 Perturbations

2015 ◽  
Vol 30 ◽  
pp. 760-794 ◽  
Author(s):  
Leonhard Batzke
Keyword(s):  
Canonical Form ◽  
Hermitian Matrix ◽  
Structure Preserving ◽  
Spectral Behavior ◽  
Generic Rank ◽  
Jordan Structure ◽  
Matrix Pencils ◽  
Rank 2 ◽  
Infinite Blocks

The spectral behavior of regular Hermitian matrix pencils is examined under certain structure-preserving rank-1 and rank-2 perturbations. Since Hermitian pencils have signs attached to real (and infinite) blocks in canonical form, it is not only the Jordan structure but also this so-called sign characteristic that needs to be examined under perturbation. The observed effects are as follows: Under a rank-1 or rank-2 perturbation, generically the largest one or two, respectively, Jordan blocks at each eigenvalue lambda are destroyed, and if lambda is an eigenvalue of the perturbation, also one new block of size one is created at lambda. If lambda is real (or infinite), additionally all signs at lambda but one or two, respectively, that correspond to the destroyed blocks, are preserved under perturbation. Also, if the potential new block of size one is real, its sign is in most cases prescribed to be the sign that is attached to the eigenvalue lambda in the perturbation.

VI.—On Singular Pencils of Zehfuss, Compound, and Schläflian Matrices

1937 ◽  
Vol 56 ◽  
pp. 50-89 ◽  
Author(s):  
W. Ledermann
Keyword(s):  
Canonical Form ◽  
Direct Product ◽  
Canonical Forms ◽  
Singular Case ◽  
Elementary Divisors ◽  
Compound Matrices ◽  
Matrix Pencils ◽  
The Subject

In this paper the canonical form of matrix pencils will be discussed which are based on a pair of direct product matrices (Zehfuss matrices), compound matrices, or Schläflian matrices derived from given pencils whose canonical forms are known.When all pencils concerned are non-singular (i.e. when their determinants do not vanish identically), the problem is equivalent to finding the elementary divisors of the pencil. This has been solved by Aitken (1935), Littlewood (1935), and Roth (1934). In the singular case, however, the so-called minimal indices or Kronecker Invariants have to be determined in addition to the elementary divisors (Turnbull and Aitken, 1932, chap. ix). The solution of this problem is the subject of the following investigation.

Modelling of Complex DEH Systems

2017 ◽  
Author(s):  
Øyvind Pharo Hanisch
Keyword(s):  
Electric Heating ◽  
The Other ◽  
Flow Assurance ◽  
Complex Field ◽  
Close Interaction ◽  
Close Proximity ◽  
Current Systems

Direct Electric Heating (DEH) is an increasingly attractive method for flow assurance that has been in use for more than 15 years. All current systems in operation consist of a single flowline or have subsea architecture such that interaction between systems as well as components in the proximity is limited. DEH is selected as flow assurance for two ongoing field developments where the layout is such that there will be interaction with other subsea architecture. One system has numerous flowline systems in close interaction and the other has unfavorable crossing. This paper presents some of the design aspects which do arise for fields where the flowlines are in close proximity to each other. The paper also discusses how to handle interference with existing infrastructure when installing DEH in a complex field layout. The aspects studied are effect on power rating, ac corrosion and thermal rating of cables and flowlines.

scholarly journals II. An eighth memoir on quantics

1867 ◽  
Vol 15 ◽  
pp. 330-331
Keyword(s):  
Simple Form ◽  
The Other ◽  
Canonical Forms ◽  
Linear Transformations ◽  
Quartic Equation ◽  
Quintic Equation ◽  
Real Equation ◽  
One Step ◽  
New Form

The present memoir relates mainly to the binary quintic, continuing the investigations in relation to this form contained in my Second, Third, and Fifth Memoirs on Quantics; the investigations which it contains in relation to a quantic of any order are given with a view to their application to the quintic. All the invariants of a binary quintic (viz. those of the degrees 4, 8, 12, and 18) are given in the memoirs above referred to, and also the covariants up to the degree 5; it was interesting to proceed one step further, viz. to the covariants of the degree 6; in fact, while for the degree 5 we obtain three covariants and a single syzygy, for the degree 6 we obtain only two covariants, but as many as seven syzygies. One of these is, however, the syzygy of the degree 5 multiplied into the quintic itself, so that, excluding this derived syzygy, there remain (7 - 1 = ) six syzygies, of the degree 6. The determination of the two covariants (Tables 83 and 84 post.), and of the syzygies of the degree 6, occupies the commencement of the present memoir. The remainder of the memoir is in a great measure a reproduction (with various additions and developments) of researches contained in Prof. Sylvester’s Trilogy, and in a recent memoir by M. Hermite. In particular, I establish in a more general form (defining for that purpose the functions which I call “Auxiliars”) the theory which is the basis of Prof. Sylvester’s criteria for the reality of the roots of a quintic. equation, or, say, the theory of the determination of the character of an equation of any order. By way of illustration, I first apply this to the quartic equation; and I then apply it to the quintic equation, following Prof. Sylvester’s track, hut so as to dispense altogether with his amphigenous surface, making the investigation to depend solely on the discussion of the bicorn curve, which is a principal section of this surface. I explain the new form which M. Hermite has given to the Tschirnhausen transformation, leading to a transformed equation, the coefficients whereof are all invariants; and, in the case of the quintic, I identify with my Tables his cubicovariants ϕ 1 ( x , y ) and ϕ 2 ( x , y ). And in the two new Tables, 85 and 86, I give the leading coefficients of the other two cubi covariants ϕ 3 ( x , y ) and ϕ 4 ( x , y ). In the transformed equation the second term (or that in z 4 ) vanishes, and the coefficient A of z 3 is obtained as a quadric function of four indeterminates. The discussion of this form led to criteria for the character of a quintic equation, expressed like those of Prof. Sylvester in terms of invariants, but of a different and less simple form; two such sets of criteria are obtained, and the identification of these and of a third set resulting from a separate investigation, with the criteria of Prof. Sylvester, is a point made out in the present memoir. The theory is also given of the canonical forms, which is the mechanism by which M. Hermite’s investigations were carried on. The memoir contains other investigations and formulae in relation to the binary quintic ; and as part of the foregoing theory of the determination of the character of an equation, I was led to consider the question of the imaginary linear transformations which give rise to a real equation : this is discussed in the concluding articles of the memoir, and in an annex I have given a somewhat singular analytical theorem arising thereout.

scholarly journals Explicit Block-Structures for Block-Symmetric Fiedler-like pencils

2018 ◽  
Vol 34 ◽  
pp. 472-499 ◽  
Author(s):  
M. I. Bueno ◽  
Madeline Martin ◽  
Javier Perez ◽  
Alexander Song ◽  
Irina Viviano
Keyword(s):  
Matrix Polynomial ◽  
Block Structure ◽  
Canonical Forms ◽  
Complex Matrix ◽  
Main Obstacle ◽  
Matrix Polynomials ◽  
Structured Matrix ◽  
Symmetric Structure ◽  
The Family ◽  
Block Structures

In the last decade, there has been a continued effort to produce families of strong linearizations of a matrix polynomial $P(\lambda)$, regular and singular, with good properties, such as, being companion forms, allowing the recovery of eigenvectors of a regular $P(\lambda)$ in an easy way, allowing the computation of the minimal indices of a singular $P(\lambda)$ in an easy way, etc. As a consequence of this research, families such as the family of Fiedler pencils, the family of generalized Fiedler pencils (GFP), the family of Fiedler pencils with repetition, and the family of generalized Fiedler pencils with repetition (GFPR) were constructed. In particular, one of the goals was to find in these families structured linearizations of structured matrix polynomials. For example, if a matrix polynomial $P(\lambda)$ is symmetric (Hermitian), it is convenient to use linearizations of $P(\lambda)$ that are also symmetric (Hermitian). Both the family of GFP and the family of GFPR contain block-symmetric linearizations of $P(\lambda)$, which are symmetric (Hermitian) when $P(\lambda)$ is. Now the objective is to determine which of those structured linearizations have the best numerical properties. The main obstacle for this study is the fact that these pencils are defined implicitly as products of so-called elementary matrices. Recent papers in the literature had as a goal to provide an explicit block-structure for the pencils belonging to the family of Fiedler pencils and any of its further generalizations to solve this problem. In particular, it was shown that all GFP and GFPR, after permuting some block-rows and block-columns, belong to the family of extended block Kronecker pencils, which are defined explicitly in terms of their block-structure. Unfortunately, those permutations that transform a GFP or a GFPR into an extended block Kronecker pencil do not preserve the block-symmetric structure. Thus, in this paper, the family of block-minimal bases pencils, which is closely related to the family of extended block Kronecker pencils, and whose pencils are also defined in terms of their block-structure, is considered as a source of canonical forms for block-symmetric pencils. More precisely, four families of block-symmetric pencils which, under some generic nonsingularity conditions are block minimal bases pencils and strong linearizations of a matrix polynomial, are presented. It is shown that the block-symmetric GFP and GFPR, after some row and column permutations, belong to the union of these four families. Furthermore, it is shown that, when $P(\lambda)$ is a complex matrix polynomial, any block-symmetric GFP and GFPR is permutationally congruent to a pencil in some of these four families. Hence, these four families of pencils provide an alternative but explicit approach to the block-symmetric Fiedler-like pencils existing in the literature.

Decanonization of modern internet-poetry on the example of genre of «pyrizhok»

2018 ◽  
pp. 58-62
Author(s):  
О. О. Вігер
Keyword(s):  
Comparative Analysis ◽  
Scientific Understanding ◽  
The Other ◽  
Canonical Forms ◽  
Modern Poetry ◽  
Huge Number ◽  
Other Hand ◽  
Literary Process ◽  
The One ◽  
Traditional Norms

Special features of a modern internet poetry-genre «pyrizhok» are reviewed in the article. The investigation of texts, which are not suited to the traditional norms of literature, is based on the scientific understanding of contemporary literary process on the part of literary scholars such as O. Rakitna, O. Yudina, T. Kononenko, K.Rakitna, M. Pekhа. Traditional canonical forms of poetry do not always satisfy the modern recipient, at the same time the new forms have not achieved sufficient evolution. Comparative analysis of traditional forms of concise poetry is made, such as tchastivka (humorous rhyme), kolomiyka (Ukrainian dance and song), sonnet, rubai from the one hand and modern forms of internet lyrics genre of «pyrizhok» and «poroshok» from the other hand. Despite “patties” («pyrizhky») are rather related with folklore, they are created by a particular author, often under the pseudonym. The presence of a particular author is akin to a “patty” with a canonical genre — rubai. This canonical genre is associated with one author — Omar Khayyam. According to authors, Vladyslav Richter is the “patties’” first creator, but his work only gave impetus to the development of the genre. A huge number of unknown authors led the genre into a category of canonical / anticononical. In this work, the complicated and contradictory character of the category “canon” is investigated. The evolution of the terms “canon” and “decanonization” in poetry comes along the process of democratization in literature. Similar features incidental to «pyrizhok» and “сomics” are found namely briefness, laconic brevity, illustrativeness and contextuality. In such a manner all the forms of internet-poetry might be considered as experimentally provocative genre. Decanonization is observed on all stages — from stylistic layer to high-principled accent. «Pyrizhok» reflects social disposition and is a part of decanonization process. In this research the attempt of provingthat «pyrizhok» is one of the most democratic genre of modern poetry is made. It is needed to be investigated by literature specialists.

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