Standard

Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. / Basov, V. V. ; Chermnykh, A. S. .

In: Vestnik St. Petersburg University: Mathematics, Vol. 50, No. 3, 2017, p. 217-234.

Research output: Contribution to journalArticlepeer-review

Harvard

Basov, VV & Chermnykh, AS 2017, 'Two-dimensional homogeneous cubic systems: Classification and normal forms: IV', Vestnik St. Petersburg University: Mathematics, vol. 50, no. 3, pp. 217-234.

APA

Basov, V. V., & Chermnykh, A. S. (2017). Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. Vestnik St. Petersburg University: Mathematics, 50(3), 217-234.

Vancouver

Basov VV, Chermnykh AS. Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. Vestnik St. Petersburg University: Mathematics. 2017;50(3):217-234.

Author

Basov, V. V. ; Chermnykh, A. S. . / Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. In: Vestnik St. Petersburg University: Mathematics. 2017 ; Vol. 50, No. 3. pp. 217-234.

BibTeX

@article{9d6065458a224cf4becced1df1bfd269,
title = "Two-dimensional homogeneous cubic systems: Classification and normal forms: IV",
abstract = "This article is the fourth in a series of works devoted to two-dimensional cubic homogeneous systems. It considers a case when a homogeneous polynomial vector in the right-hand part of the system has a quadratic common factor with complex zeros. A set of such systems is divided into classes of linear equivalence, wherein the simplest system is distinguished on the basis of properly introduced structural and normalization principles, being, thus, the third-order normal form. In fact, such a form is defined by a matrix of its right-hand part coefficients, which is called the canonical form (CF). Each CF has its own arrangement of nonzero elements, their specific normalization and canonical set of permissible values for the nonnormalized elements, which relates CF to a selected class of equivalence. In addition, each CF is characterized by: (1) conditions imposed on the coefficients of the initial system, (2) nonsingular linear substitutions that transform the right-hand part of the system under these conditions into a selected CF, and (3) obtained values of CF{\textquoteright}s nonnormalized elements.",
keywords = "homogeneous cubic system, normal form, canonical form",
author = "Basov, {V. V.} and Chermnykh, {A. S.}",
note = "Basov, V.V., Chermnykh, A.S. Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. Vestnik St.Petersb. Univ.Math. 50, 217–234 (2017). https://doi.org/10.3103/S1063454117030049",
year = "2017",
language = "English",
volume = "50",
pages = "217--234",
journal = "Vestnik St. Petersburg University: Mathematics",
issn = "1063-4541",
publisher = "Pleiades Publishing",
number = "3",

}

RIS

TY - JOUR

T1 - Two-dimensional homogeneous cubic systems: Classification and normal forms: IV

AU - Basov, V. V.

AU - Chermnykh, A. S.

N1 - Basov, V.V., Chermnykh, A.S. Two-dimensional homogeneous cubic systems: Classification and normal forms: IV. Vestnik St.Petersb. Univ.Math. 50, 217–234 (2017). https://doi.org/10.3103/S1063454117030049

PY - 2017

Y1 - 2017

N2 - This article is the fourth in a series of works devoted to two-dimensional cubic homogeneous systems. It considers a case when a homogeneous polynomial vector in the right-hand part of the system has a quadratic common factor with complex zeros. A set of such systems is divided into classes of linear equivalence, wherein the simplest system is distinguished on the basis of properly introduced structural and normalization principles, being, thus, the third-order normal form. In fact, such a form is defined by a matrix of its right-hand part coefficients, which is called the canonical form (CF). Each CF has its own arrangement of nonzero elements, their specific normalization and canonical set of permissible values for the nonnormalized elements, which relates CF to a selected class of equivalence. In addition, each CF is characterized by: (1) conditions imposed on the coefficients of the initial system, (2) nonsingular linear substitutions that transform the right-hand part of the system under these conditions into a selected CF, and (3) obtained values of CF’s nonnormalized elements.

AB - This article is the fourth in a series of works devoted to two-dimensional cubic homogeneous systems. It considers a case when a homogeneous polynomial vector in the right-hand part of the system has a quadratic common factor with complex zeros. A set of such systems is divided into classes of linear equivalence, wherein the simplest system is distinguished on the basis of properly introduced structural and normalization principles, being, thus, the third-order normal form. In fact, such a form is defined by a matrix of its right-hand part coefficients, which is called the canonical form (CF). Each CF has its own arrangement of nonzero elements, their specific normalization and canonical set of permissible values for the nonnormalized elements, which relates CF to a selected class of equivalence. In addition, each CF is characterized by: (1) conditions imposed on the coefficients of the initial system, (2) nonsingular linear substitutions that transform the right-hand part of the system under these conditions into a selected CF, and (3) obtained values of CF’s nonnormalized elements.

KW - homogeneous cubic system

KW - normal form

KW - canonical form

UR - https://link.springer.com/article/10.3103/S1063454117030049

M3 - Article

VL - 50

SP - 217

EP - 234

JO - Vestnik St. Petersburg University: Mathematics

JF - Vestnik St. Petersburg University: Mathematics

SN - 1063-4541

IS - 3

ER -

ID: 35254557