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Izvestiya of Saratov University. Mathematics. Mechanics. Informatics, 2011, Volume 11, Issue 3(1), Pages 61–89
DOI: https://doi.org/10.18500/1816-9791-2011-11-3-1-61-89 (Mi isu236) 		 
This article is cited in 10 scientific papers (total in 10 papers)

Mechanics

Finite integral transformations method – generalization of classic procedure for eigenvector decomposition

Yu. E. Senitsky

Samara State University of Architecture and Civil Engineering, Chair of Resistance of Materials and Construction Mechanics
Full-text PDF (960 kB) Citations (10)
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DOI: https://doi.org/10.18500/1816-9791-2011-11-3-1-61-89
Abstract: The structural algorithm of the finite integral transformation method is presented as a generalization of the classical procedure of eigenvector decomposition. The initial-boundary problems described with a hyperbolic system of linear partial second order differential equations are considered. The general case of non-self adjoint solution by expansion in the vector-functions is possible only by the use of biorthogonal of finite integral transformations. In particular, for self-adjoint initial-boundary problems solutions obtained by the method of finite integral transforms and the classic procedure of eigenvector decomposition expansion are identical, although the first of these is preferable. These statements are illustrated by the example of a closed solution of the dynamic problem for a three-layer anisotropic elastic cylindrical shell under the general conditions of loading and fastening on the circuit.
Key words: method, generalized algorithm, finite integral transformations, multicomponent ability, biorthogonality, special decomposition, vector-functions, boundary value problems, self-adjoint, non-self adjointness, hyperbolic equations, solution existence, convergency, singularity, integrality, cylindrical shell, tri-plies, refined theory, closed solution.
Document Type: Article
UDC: 517.958
Language: Russian
Citation: Yu. E. Senitsky, “Finite integral transformations method – generalization of classic procedure for eigenvector decomposition”, Izv. Saratov Univ. Math. Mech. Inform., 11:3(1) (2011), 61–89
Citation in format AMSBIB
\Bibitem{Sen11}
\by Yu.~E.~Senitsky
\paper Finite integral transformations method~-- generalization of classic procedure for eigenvector decomposition
\jour Izv. Saratov Univ. Math. Mech. Inform.
\yr 2011
\vol 11
\issue 3(1)
\pages 61--89
\mathnet{http://mi.mathnet.ru/isu236}
\crossref{https://doi.org/10.18500/1816-9791-2011-11-3-1-61-89}
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    • This publication is cited in the following 10 articles:
    1. D. A. Shlyakhin, E. V. Savinova, “Coupled Axisymmetric Thermoelectroelasticity Problem for a Round Rigidly Fixed Plate”, Vestnik Donskogo gosudarstvennogo tehničeskogo universiteta, 24:1 (2024), 23  crossref
    2. Ya. M. Grigorenko, O. I. Bespalova, “Generalized Method of Finite Integral Transformations in Linear and Nonlinear Static Problems for Shallow Shells”, J Math Sci, 274:5 (2023), 618  crossref
    3. Dmitriy Kretov, Lecture Notes in Civil Engineering, 189, XXX Russian-Polish-Slovak Seminar Theoretical Foundation of Civil Engineering (RSP 2021), 2022, 123  crossref
    4. O. I. Bespalova, “Nonlinear Deformation of Discretely Inhomogeneous Shallow Shells Based on the Generalized Method of Finite Integral Transforms*”, Int Appl Mech, 58:5 (2022), 569  crossref
    5. Ya. M. Grigorenko, O. I. Bespalova, “The generalized finite integral transformations method in linear and nonlinear static problems for shallow shells”, Mat. Met. Fiz. Mekh. Polya, 64:1 (2021)  crossref
    6. M. A. Kalmova, “Dynamic inverse piezo-effect problem for a long piezoceramic thermoelastic cylinder”, Vestn. Dagest. gos. teh. univ., Teh. nauki, 47:4 (2021), 57  crossref
    7. T. B. Elekina, E. S. Vronskaya, “Dinamicheskaya zadacha dlya tonkostennogo sterzhnya monosimmetrichnogo profilya”, Vestn. SamU. Estestvennonauchn. ser., 26:2 (2020), 63–69  mathnet  crossref
    8. Sergei M. Sitnik, Oleg Yaremko, Natalia Yaremko, Trends in Mathematics, Transmutation Operators and Applications, 2020, 447  crossref
    9. Dmitrij Averkievich Shlyahin, Olesya Viktorovna Ratmanova, “Dynamic Axisymmetric Problem of Direct Piezoelectric Effect for A Bimorphic Plate of Stepwise Variable Thickness”, IOP Conf. Ser.: Mater. Sci. Eng., 661:1 (2019), 012009  crossref
    10. Bespalova E.I., “Generalized Method of Finite Integral Transforms in Static Problems For Anisotropic Prisms”, Int. Appl. Mech., 54:1 (2018), 41–55  crossref  mathscinet  zmath  isi  scopus
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