An alternative analysis technique, which does not require eigensolutions as a priori, for the dynamic response solutions, in terms of the transfer function, of one-dimensional distributed parameter systems with arbitrary supporting conditions, is presented. The technique is based on the fact that the dynamic displacement of any point in a waveguide can be determined by superimposing the amplitudes of the wave components traveling along the waveguide, where the wave numbers of the constituent waves are defined in the Laplace domain instead of the frequency domain. The spatial amplitude variations of individual waves are represented by the field transfer matrix and the distortions of the wave amplitudes at point discontinuities due to constraints or boundaries are described by the wave reflection and transmission matrices. Combining these matrices in a progressive manner along the waveguide using the concepts of generalized wave reflection and transmission matrices leads to the exact transfer function of a complex distributed parameter system subjected to an externally applied force. The transient response solution can be obtained through the Laplace inversion using the fixed Talbot method. The exact frequency response solution, which includes infinite normal modes of the system, can be obtained in terms of the complex frequency response function from the system’s transfer function. This wave-based analysis technique is applicable to any one-dimensional viscoelastic structure (strings, axial rods, torsional bar, and beams), in particular systems with multiple point discontinuities such as viscoelastic supports, attached mass, and geometric/material property changes. In this paper, the proposed approach is applied to the flexural vibration analysis of a classical Euler–Bernoulli beam with multiple spans to demonstrate its systematic and recursive formulation technique.
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April 2007
Technical Papers
Transfer Functions of One-Dimensional Distributed Parameter Systems by Wave Approach
B. Kang
B. Kang
Professor
Department of Mechanical Engineering,
e-mail: kang@engr.ipfw.edu
Indiana University – Purdue University Fort Wayne
, Fort Wayne, Indiana 46805-1499
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B. Kang
Professor
Department of Mechanical Engineering,
Indiana University – Purdue University Fort Wayne
, Fort Wayne, Indiana 46805-1499e-mail: kang@engr.ipfw.edu
J. Vib. Acoust. Apr 2007, 129(2): 193-201 (9 pages)
Published Online: September 29, 2006
Article history
Received:
July 18, 2005
Revised:
September 29, 2006
Citation
Kang, B. (September 29, 2006). "Transfer Functions of One-Dimensional Distributed Parameter Systems by Wave Approach." ASME. J. Vib. Acoust. April 2007; 129(2): 193–201. https://doi.org/10.1115/1.2424972
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