论文信息 - High frequency vibration analysis by the complex envelope vectorization.

High frequency vibration analysis by the complex envelope vectorization.

The complex envelope displacement analysis (CEDA) is a procedure to solve high frequency vibration and vibro-acoustic problems, providing the envelope of the physical solution. CEDA is based on a variable transformation mapping the high frequency oscillations into signals of low frequency content and has been successfully applied to one-dimensional systems. However, the extension to plates and vibro-acoustic fields met serious difficulties so that a general revision of the theory was carried out, leading finally to a new method, the complex envelope vectorization (CEV). In this paper the CEV method is described, underlying merits and limits of the procedure, and a set of applications to vibration and vibro-acoustic problems of increasing complexity are presented.

A Carcaterra | O Giannini | A Sestieri

[1] Antonio Carcaterra,et al. COMPLEX ENVELOPE DISPLACEMENT ANALYSIS: A QUASI-STATIC APPROACH TO VIBRATIONS , 1997 .

[2] Richard L. Weaver,et al. ANDERSON LOCALIZATION IN COUPLED REVERBERATION ROOMS , 2000 .

[3] Robert J. Bernhard,et al. Mechanical energy flow models of rods and beams , 1992 .

[4] Mohamed Ichchou,et al. ENERGY MODELS OF ONE-DIMENSIONAL, MULTI-PROPAGATIVE SYSTEMS , 1997 .

[5] Robin S. Langley,et al. A wave intensity technique for the analysis of high frequency vibrations , 1992 .

[6] Richard L. Weaver,et al. Towards a diffusion model of acoustic energy flow in large undamped structures , 2005 .

[7] Earl H. Dowell,et al. Dynamics of Very High Dimensional Systems , 2003 .

[8] Brian R. Mace. Statistical energy analysis, energy distribution models and system modes , 2003 .

[9] R. Langley,et al. A hybrid method for the vibration analysis of complex structural-acoustic systems , 1999 .

[10] R. Langley,et al. Vibro-acoustic analysis of complex systems , 2005 .

[11] Antonio Carcaterra,et al. Ensemble energy average and energy flow relationships for nonstationary vibrating systems , 2005 .

[12] A. Le Bot,et al. Geometric Diffusion of Vibrational Energy and Comparison with the Vibrational Conductivity Approach , 1998 .

[13] R. Lyon,et al. Power Flow between Linearly Coupled Oscillators , 1962 .