AN ENERGY-BASED FORMULATION FOR COMPUTING NONLINEAR NORMAL-MODES IN UNDAMPED CONTINUOUS SYSTEMS

被引：52

作者：

KING, ME

VAKAKIS, AF

机构：

[1] Department of Mechanical and Industrial Engineering, University of Illinois at Urbana-Champaign, Urbana, IL

来源：

JOURNAL OF VIBRATION AND ACOUSTICS-TRANSACTIONS OF THE ASME | 1994年 / 116卷 / 03期

关键词：

Computational methods - Differential equations - Nonlinear equations - Numerical analysis - Perturbation techniques - Polynomials - Topology - Vibrations (mechanical);

D O I：

10.1115/1.2930433

中图分类号：

O42 [声学];

学科分类号：

070206 ; 082403 ;

摘要：

The nonlinear normal modes of a class of one-dimensional, conservative, continuous systems are examined. These are free, periodic motions during which all particles of the system reach their extremum amplitudes at the same instant of time. During a nonlinear normal mode, the motion of an arbitrary particle of the system is expressed in terms of the motion of a certain reference point by means of a modal function. Conservation of energy is imposed to construct a partial differential equation satisfied by the modal function, which is asymptotically solved using a perturbation methodology. The stability of the detected nonlinear modes is then investigated by expanding the corresponding variational equations in bases of orthogonal polynomials and analyzing the resulting set of linear differential equations with periodic coefficients by Floquet analysis. Applications of the general theory are given by computing the nonlinear normal modes of a simply-supported beam lying on a nonlinear elastic foundation, and of a cantilever beam possessing geometric nonlinearities.

引用

页码：332 / 340

页数：9

共 20 条

[1]

Caughey T.K., Vakakis A.F., Sivo J., Analytical Study of Similar Normal Modes and Their Bifurcations in a Class of Strongly Nonlinear Systems, International Journal of Non-Linear Mechanics, 25, 5, pp. 521-533, (1990)

[2]

Cooke C.H., Struble R.A., On the Existence of Periodic Solutions and Normal Mode Vibrations of Nonlinear Systems, Quarterly of Applied Mathematics, 24, 3, pp. 177-193, (1966)

[3]

Crespo Da Silva M.R.M., Glynn C.C., Nonlinear Flexural-Torsional Dynamics of Inextensional Beams I: Equations of Motion and II: Forced Motions, Journal of Structural Mechanics, 6, 4, pp. 437-461, (1978)

[4]

Manevitch L., Mikhlin I., On Periodic Solutions Close to Rectilinear Normal Vibration Modes, PMM, 36, 6, pp. 1051-1058, (1972)

[5]

Mikhlin I., Resonance Modes of Near-Conservative Nonlinear Systems, PMM, 38, 3, pp. 459-464, (1974)

[6]

Month L., Rand R.H., The Stability of Bifurcating Periodic Solutions in a Two-Degree-of-Freedom Nonlinear System, ASME Journal of Applied Mechanics, 44, pp. 782-783, (1977)

[7]

Nayfeh A., Mook D., Nonlinear Oscillations, (1985)

[8]

Rand R.H., Pak C.H., Vakakis A.F., Bifurcation of Nonlinear Normal Modes in a Class of Two-Degree-of-Freedom Systems, Acta Mechan-Ica, 3, pp. 129-145, (1992)

[9]

Rosenberg R.M., On The Existence of Normal Mode Vibrations of Nonlinear Systems With Two-Degrees-of-Freedom, Quarterly of Applied Mathematics, 22, 3, pp. 217-234, (1964)

[10]

Rosenberg R.M., On Nonlinear Vibrations of Systems With Many Degrees-of-Freedom, Advances in Applied Mechanics, 9, pp. 155-242, (1966)

← 1 2 →