Journal article
A machine learning accelerated inverse design of underwater acoustic polyurethane coatings
H Weeratunge, Z Shireen, S Iyer, A Menzel, AW Phillips, S Halgamuge, R Sandberg, E Hajizadeh
Structural and Multidisciplinary Optimization | Published : 2022
Open access
Abstract
Here we propose a detailed protocol to enable an accelerated inverse design of acoustic coatings for underwater sound attenuation application by coupling Machine Learning and an optimization algorithm with Finite Element Models (FEM). The FEMs were developed to obtain the realistic performance of the polyurethane (PU) acoustic coatings with embedded cylindrical voids. The frequency dependent viscoelasticity of PU matrix is considered in FEM models to substantiate the impact on absorption peak associated with the embedded cylinders at low frequencies. This has been often ignored in previous studies of underwater acoustic coatings, where usually a constant frequency-independent complex modulus..
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Funding Acknowledgements
This research is supported by the Commonwealth of Australia as represented by the Defence Science and Technology Group of the Department of Defence. We acknowledge Melbourne Research Cloud at Faculty of Engineering and Information Technology, The University of Melbourne for providing us the computing facility.