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Article Dans Une Revue Nonlinear Analysis: Hybrid Systems Année : 2021

D'Alembert function for exact non-smooth modal analysis of the bar in unilateral contact

Résumé

Non-smooth modal analysis is an extension of modal analysis to non-smooth systems, prone to unilateral contact conditions for instance. The problem of a one-dimensional bar subject to unilateral contact on its boundary has been previously investigated numerically and the corresponding spectrum of vibration could be partially explored. In the present work, the non-smooth modal analysis of the above system is reformulated as a set of functional equations through the use of both d'Alembert solution to the wave equation and the method of steps for Neutral Delay Differential Equations. The system features a strong internal resonance condition and it is found that irrational and rational periods of vibration should be carefully distinguished. For irrational periods, the displacement field of the non-smooth modes of vibration consist in piecewise-linear functions of space and time and such a motion is unique for a prescribed energy. However, for rational periods, new periodic solutions are found analytically. They belong to families of iso-periodic solutions with piecewise-smooth displacement field in space and time.
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Dates et versions

hal-02984137 , version 1 (30-10-2020)
hal-02984137 , version 2 (17-11-2021)

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Paternité - Pas d'utilisation commerciale

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David Urman, Mathias Legrand, Stéphane Junca. D'Alembert function for exact non-smooth modal analysis of the bar in unilateral contact. Nonlinear Analysis: Hybrid Systems, 2021, ⟨10.1016/j.nahs.2021.101115⟩. ⟨hal-02984137v2⟩
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