A hybrid approach for predicting the distribution of vibro-acoustic energy in complex built-up structures

TL;DR

This paper introduces a hybrid modeling approach combining FEM and SEA to predict vibro-acoustic energy distribution in complex structures, effectively addressing the mid-frequency problem by leveraging local wavelength information.

Contribution

A novel hybrid method that couples FEM and SEA based on local wavelength analysis to improve vibro-acoustic energy predictions in complex structures.

Findings

Effective prediction of energy distribution in complex structures.

Hybrid approach reduces computational complexity.

Addresses mid-frequency modeling challenges.

Abstract

Finding the distribution of vibro-acoustic energy in complex built-up structures in the mid-to-high frequency regime is a difficult task. In particular, structures with large variation of local wavelengths and/or characteristic scales pose a challenge referred to as the mid-frequency problem. Standard numerical methods such as the finite element method (FEM) scale with the local wavelength and quickly become too large even for modern computer architectures. High frequency techniques, such as statistical energy analysis (SEA), often miss important information such as dominant resonance behaviour due to stiff or small scale parts of the structure. Hybrid methods circumvent this problem by coupling FEM/BEM and SEA models in a given built-up structure. In the approach adopted here, the whole system is split into a number of subsystems which are treated by either FEM or SEA depending on the local wavelength. Subsystems with relative long wavelengths are modelled using FEM. Making a diffuse field assumption for the wave fields in the short wave length components, the coupling between subsystems can be reduced to a weighted random field correlation function. The approach presented results in an SEA-like set of linear equations which can be solved for the mean energies in the short wavelength subsystems.