Strongly Nonlinear Vibrations

Some significant behaviors on strongly nonlinear vibrations are examined for a thin-walled cylindrical shell composed of the classical incompressible Mooney–Rivlin material and subjected to a single radial harmonic excitation at the inner surface. First, with the aid of Donnell’s nonlinear shallow-shell theory, Lagrange’s equations and the assumption of small strains, a nonlinear system of differential equations for the large deflection vibration of a thin-walled shell is obtained. Second, based on the condensation method, the nonlinear system of differential equations is reduced to a strongly nonlinear Duffing equation with a large parameter. Finally, by the appropriate parameter transformation and modified Lindstedt–Poincar[Formula: see text] method, the response curves for the amplitude-frequency and phase-frequency relations are presented. Numerical results demonstrate that the geometrically nonlinear characteristic of the shell undergoing large vibrations shows a hardening behavior, while the nonlinearity of the hyperelastic material should weak the hardening behavior to some extent.

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Application of modified Mickens iteration procedure to a pendulum and the motion of a mass attached to a stretched elastic wire

International Journal of Nonlinear Sciences and Numerical Simulation ◽

10.1515/ijnsns-2020-0256 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Amin Gholami ◽

Davood D. Ganji ◽

Hadi Rezazadeh ◽

Waleed Adel ◽

Ahmet Bekir

Keyword(s):

Approximate Solution ◽

Nonlinear Vibrations ◽

Nonlinear Problems ◽

Iterative Approach ◽

Mathematical Pendulum ◽

Science And Engineering ◽

Strongly Nonlinear ◽

Strongly Nonlinear System ◽

Strong Candidate ◽

Iteration Technique

Abstract The paper deals with the application of a strong method called the modified Mickens iteration technique which is used for solving a strongly nonlinear system. The system describes the motion of a simple mathematical pendulum with a particle attached to it through a stretched wire. This model has great applications especially in the area of nonlinear vibrations and oscillation systems. The proposed method depends on determining the frequency and amplitude of the system through the modified Mickens iterative approach which is a modification of the regular Mickens approach. The preliminaries of the proposed technique are present and the application to the model is discussed. The method depends on the Mickens iteration approach which transforms the considered equation into a linear form and then is solving this equation result in the approximate solution. Some examples are given to validate and illustrate the effectiveness and convenience of the method. These results are compared with other relative techniques from the literature in terms of finding the frequency of the two examined models. The method produces more accurate results when compared to these methods and is considered a strong candidate for solving other nonlinear problems with applications in science and engineering.

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On the Approximate Analytical Solution to Non-Linear Oscillation Systems

Shock and Vibration ◽

10.1155/2013/549213 ◽

2013 ◽

Vol 20 (1) ◽

pp. 43-52 ◽

Cited By ~ 41

Author(s):

Mahmoud Bayat ◽

Iman Pakar

Keyword(s):

Variational Approach ◽

Nonlinear Vibrations ◽

Approximate Analytical Solution ◽

Nonlinear Oscillators ◽

The Other ◽

Lumped Mass ◽

Strongly Nonlinear ◽

Constant Coefficients ◽

Linear Oscillation ◽

Elastically Restrained

This study describes an analytical method to study two well-known systems of nonlinear oscillators. One of these systems deals with the strongly nonlinear vibrations of an elastically restrained beam with a lumped mass. The other is a Duffing equation with constant coefficients. A new implementation of the Variational Approach (VA) is presented to obtain highly accurate analytical solutions to free vibration of conservative oscillators with inertia and static type cubic nonlinearities. In the end, numerical comparisons are conducted between the results obtained by the Variational Approach and numerical solution using Runge-Kutta's [RK] algorithm to illustrate the effectiveness and convenience of the proposed methods.

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