Wave propagation, reflection and transmission in non-uniform one-dimensional waveguides
Wave propagation, reflection and transmission in non-uniform one-dimensional waveguides
Waves can propagate freely without reflection in a certain class of non-uniform one-dimensional waveguides even though the properties of the waveguide vary rapidly. In these cases, the amplitude of the wave changes as a function of position but the power associated with the wave is preserved along the waveguide as in uniform waveguides. A generalised wave approach based on reflection, transmission and propagation of waves is used for the analysis of such non-uniform waveguides. The positive- and negative-going wave motions are separated so that the problem is always well-posed. Examples include longitudinal motion of bars and bending motion of Euler–Bernoulli beams, where the cross-section varies as a power of the length. The energy transport velocity, which is the velocity at which energy is carried by the waves in these waveguides, is derived using the relationship between power and energy. It is shown that this energy transport velocity depends on position as well as frequency and differs from the group velocity. Numerical results for wave transmission through a rectangular connector with linearly tapered thickness and constant width are obtained in a straightforward manner without approximation errors and at a low computational cost, irrespective of frequency.
31-49
Lee, S.K.
2bda7741-8d13-42f7-937a-a865fe2df798
Mace, B.R.
cfb883c3-2211-4f3a-b7f3-d5beb9baaefe
Brennan, M.J.
87c7bca3-a9e5-46aa-9153-34c712355a13
10 July 2007
Lee, S.K.
2bda7741-8d13-42f7-937a-a865fe2df798
Mace, B.R.
cfb883c3-2211-4f3a-b7f3-d5beb9baaefe
Brennan, M.J.
87c7bca3-a9e5-46aa-9153-34c712355a13
Lee, S.K., Mace, B.R. and Brennan, M.J.
(2007)
Wave propagation, reflection and transmission in non-uniform one-dimensional waveguides.
Journal of Sound and Vibration, 304 (1-2), .
(doi:10.1016/j.jsv.2007.01.039).
Abstract
Waves can propagate freely without reflection in a certain class of non-uniform one-dimensional waveguides even though the properties of the waveguide vary rapidly. In these cases, the amplitude of the wave changes as a function of position but the power associated with the wave is preserved along the waveguide as in uniform waveguides. A generalised wave approach based on reflection, transmission and propagation of waves is used for the analysis of such non-uniform waveguides. The positive- and negative-going wave motions are separated so that the problem is always well-posed. Examples include longitudinal motion of bars and bending motion of Euler–Bernoulli beams, where the cross-section varies as a power of the length. The energy transport velocity, which is the velocity at which energy is carried by the waves in these waveguides, is derived using the relationship between power and energy. It is shown that this energy transport velocity depends on position as well as frequency and differs from the group velocity. Numerical results for wave transmission through a rectangular connector with linearly tapered thickness and constant width are obtained in a straightforward manner without approximation errors and at a low computational cost, irrespective of frequency.
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Published date: 10 July 2007
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Local EPrints ID: 46584
URI: http://eprints.soton.ac.uk/id/eprint/46584
ISSN: 0022-460X
PURE UUID: fe42ba06-0285-4397-ba6d-0ee4de0db78a
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Date deposited: 06 Jul 2007
Last modified: 15 Mar 2024 09:24
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Author:
S.K. Lee
Author:
M.J. Brennan
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