Title of article
Lie Symmetry Analysis and Approximate Solutions for Non-linear Radial Oscillations of an Incompressible Mooney]Rivlin Cylindrical Tube
Author/Authors
D. P. Mason1 and N. Roussos، نويسنده ,
Issue Information
دوهفته نامه با شماره پیاپی سال 2000
Pages
47
From page
346
To page
392
Abstract
The non-linear, second-order differential equation derived by Knowles 1960,
Quart. Appl. Math. 18, 71]77. which governs the axisymmetric radial oscillations of
an infinitely long, hyperelastic cylindrical tube of Mooney]Rivlin material is
considered. It is shown that if the boundary conditions are time dependent, then
the Knowles equation has no Lie point symmetries, while if the boundary conditions
are constant it has one Lie point symmetry corresponding to time transla-
tional invariance. The derivation by Knowles 1962, J. Appl. Mech. 29, 283]286.of
bounds on the period of the oscillation for the heaviside step loading boundary
condition is extended to obtain limiting oscillations that exhibit periods that bound
the exact period above and below. The Knowles equation for a Mooney]Rivlin
material is expanded in powers of a dimensionless parameter, m, defined in terms
of the thickness of the tube wall. To zero order in m an Ermakov]Pinney equation
is obtained which has three Lie point symmetries. It is shown that the differential
equation which is correct to first order in m also has three Lie point symmetries
which disappear at second order in m. For time independent boundary conditions,
the three Lie point symmetries of the order m equation are derived explicitly and
the associated first integrals are obtained. The general solution is derived in terms
of the three first integrals and it is illustrated for free oscillations and the heaviside
step loading boundary condition. The non-autonomous first order in m equation is
transformed to an autonomous Ermakov]Pinney equation and a non-linear superposition
principle for the solution to first order in m is derived and applied to a
blast loaded applied pressure that decays linearly with time. The solutions to first
order in m are compared with numerical solutions of the Knowles equation for a
thick-walled cylinder and are found to be more accurate than the zero order
solutions described by the Ermakov]Pinney equation.
Keywords
finite elasticity , Lie point symmetries , Symmetry breaking , limitingoscillations , First integrals , non-linear superposition , Ermakov]Pinney equation
Journal title
Journal of Mathematical Analysis and Applications
Serial Year
2000
Journal title
Journal of Mathematical Analysis and Applications
Record number
933141
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