Abstract

Random excitation of mechanical systems occurs in a wide variety of structures and, in some applications, calculation of the power dissipated by such a system will be of interest. In this paper, using the Wiener series, a general methodology is developed for calculating the power dissipated by a general nonlinear multi-degree-of freedom oscillatory system excited by random Gaussian base motion of any spectrum. The Wiener series method is most commonly applied to systems with white noise inputs, but can be extended to encompass a general non-white input. From the extended series a simple expression for the power dissipated can be derived in terms of the first term, or kernel, of the series and the spectrum of the input. Calculation of the first kernel can be performed either via numerical simulations or from experimental data and a useful property of the kernel, namely that the integral over its frequency domain representation is proportional to the oscillating mass, is derived. The resulting equations offer a simple conceptual analysis of the power flow in nonlinear randomly excited systems and hence assist the design of any system where power dissipation is a consideration. The results are validated both numerically and experimentally using a base-excited cantilever beam with a nonlinear restoring force produced by magnets.

Highlights

  • Due to the diverse range of vibration sources encountered in engineering structures, a variety of different forms of excitation drive vibration

  • The first Wiener kernel must be calculated from either simulations or experimentally using Eq (11), but crucially for a designer of a system desiring a preliminary estimate of power dissipation, the first Wiener kernel has the property of Eq (40) where the triple product term is equal to the oscillating mass provided the system is unconstrained

  • A methodology has been presented for calculating the power dissipated by nonlinear MDOF systems under general random base excitation

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Summary

Introduction

Due to the diverse range of vibration sources encountered in engineering structures, a variety of different forms of excitation drive vibration. Of particular interest here are general methods for calculating power dissipation of nonlinear systems from random excitation. [6] and shows that for a general multi-degree-of-freedom (MDOF) nonlinear system subject to white noise base excitation, the power dissipated is proportional to the total oscillating mass and the magnitude of the noise spectrum regardless of the specific details of the system. The Wiener series is a useful method for analysing an output from a nonlinear system with a Gaussian white noise input via an orthogonal series expansion of the random output [16].

Wiener series for non-white excitation
Calculating the first kernel
Calculating power from the extended Wiener series
Properties of the first extended Wiener kernel
Numerical validation
Single-degree-of-freedom system
Multi-degree-of-freedom system
Experimental validation
Findings
Conclusions
Full Text
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