| | Journal of Applied Mathematics and Mechanics Russian Academy of Sciences | | Founded
in January 1936
(Translated from 1958)
Issued 6 times a year
ISSN 0021-8928 (print version) |
Archive of Issues
Total articles in the database: | | 10522 |
In Russian (ΟΜΜ): | | 9723
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In English (J. Appl. Math. Mech.): | | 799 |
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<< Previous article | Volume 75, Issue 1 / 2011 | Next article >> |
A.G. Kulikovskii and E.I. Sveshnikova, "Near-resonace transverse oscillations in an elastic layer. Steady-state solutions," J. Appl. Math. Mech. 75 (1), 19-26 (2011) |
Year |
2011 |
Volume |
75 |
Issue |
1 |
Pages |
19-26 |
Title |
Near-resonace transverse oscillations in an elastic layer. Steady-state solutions |
Author(s) |
A.G. Kulikovskii (Moscow, Russia, kulik@mi.ras.ru)
E.I. Sveshnikova (Moscow, Russia) |
Abstract |
The solutions of the equations of the non-linear evolution of transverse oscillations in a layer of an incompressible elastic medium under conditions close to resonance conditions are investigated qualitatively and using analytical methods. The oscillations are created by a small periodic motion of one of the boundaries in its plane, with a period that is close to the period of the natural oscillations of the layer. It is assumed that the medium can possess slight anisotropy and that the amplitude of the oscillations which arise is small. Previously obtained differential equations are used, which describe the slow evolution of the wave pattern of non-linear transverse waves. Two possible formulations of problems for these equations are considered. In the first formulation, it is determined what the external action must be in order that the non-linear evolution of oscillations or periodic oscillations occurs according to a (previously specified) desired law. In the second formulation it is assumed that the periodic motion of one of the boundaries is given. It is shown that a steady-state solution, that does not vary from period to period, can be represented by a continuous solution and also by a solution which contains discontinuities in the strain and velocity components. The mechanism of the overturn of a non-linear wave during its evolution and the formation of a discontinuity are qualitatively described. |
Received |
03 December 2009 |
Link to Fulltext |
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