Abstract
The artificial neural networks approach is applied to estimate the acoustic performance for airborne and impact sound insulation curves of different lightweight wooden floors. The prediction model is developed based on 252 standardized laboratory measurement curves in one-third octave bands (50–5000 Hz). Physical and geometric characteristics of each floor structure (materials, thickness, density, dimensions, mass and more) are utilized as network parameters. The predictive capability is satisfactory, and the model can estimate airborne sound better than impact sound cases especially in the middle-frequency range (250–1000 Hz), while higher frequency bands often show high errors. The forecast of the weighted airborne sound reduction index Rw was calculated with a maximum error of 2 dB. However, the error increased up to 5 dB in the worse case prediction of the weighted normalized impact sound pressure level Ln,w. The model showed high variations near the fundamental and critical frequency areas which affect the accuracy. A feature attribution analysis explored the essential parameters on estimation of sound insulation. The thickness of the insulation materials, the density of cross-laminated timber slab and the concrete floating floors and the total density of floor structures seem to affect predictions the most. A comparison between wet and dry floor solution systems indicated the importance of the upper part of floors to estimate airborne and impact sound in low frequencies.
Highlights
The goal of this study is to develop a prediction tool based on artificial neural networks for airborne and impact sound insulation estimation of different floor structures
After training and validating the model with 202 and 24 laboratory measurements, respectively, another 24 sound insulation curves are chosen randomly to test the accuracy of the artificial neural networks (ANNs) model (12 for airborne reduction index and 12 for impact sound pressure levels)
The results show that the thickness of the insulation materials is vital in the higher frequency range
Summary
Controlling the acoustic environment in building constructions is an essential aspect of new as well as old renovated buildings [1], especially dwellings. Improving the perception of the acoustic comfort for the building users is critical for research, development and design of contemporary constructions [2]. The sound insulation data of existing building elements are derived from standardized measurements and used as an indication or usually prediction for the performance of building components in a new structure. Such measurements can happen in situ or various test building elements may be set up in a laboratory, e.g., to test insulation of wall or floor partitions [3–9]
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