Background <p>Long-standing research on the relationship between the urban acoustic environment (AE) and human health demonstrates the harmful effects of environmental noise. Meanwhile, an increasing number of smaller studies report health benefits for additional acoustic properties. However, studies on health-promoting AEs remain limited, largely due to the lack of methods for estimating high-resolution acoustic properties beyond conventional noise metrics.</p> Objective <p>We investigate to what extent models based on land-use types (LUT) can predict urban AE properties, focusing on four acoustic indices (Articulation Index, Bioacoustic Index, Link Density and Sharpness). Additionally, we predict the LAeq, which enables us to compare the performance between our model, the strategic noise map of Bochum (SNM) and results from the literature.</p> Methods <p>We use a dataset of 2,746 acoustic measurements from 785 locations in Bochum and 90 measurements from 22 locations in Essen to train and evaluate gradient boosting models. For model development, data is split into training/validation (668 locations in Bochum) and test sets (117 locations in Bochum, all locations in Essen). The models predict acoustic indices based on the area of 77 LUTs within 50 and 300 m buffers around each location.</p> Results <p>Based on the root mean square error (RMSE), predictions for Link Density deviate on average by 0.17 and 0.21 from test-sets in Bochum and Essen. For LAeq, the RMSE is 4.8 dB(A) and 4.4 dB(A), respectively. The <i>R</i><sup>2</sup> for Link Density is between 0.27 and 0.3, and for the LAeq between 0.52 and 0.46. The SNM performs worse in predicting LAeq for Bochum data (RMSE = 7.8 dB(A); <i>R</i><sup>2</sup> = –0.31). Performances for other indices are mixed.</p> Impact <p>This study advances research on the urban acoustic environment by demonstrating that land use type-based models represent a promising approach to predict acoustic indices beyond conventional noise metrics. Using over 2,800 measurements from two German cities, the models for predicting the Link Density and the LAeq show moderate to good performance on two test datasets. Model predictions for the LAeq outperformed strategic noise maps in predicting total environmental noise. These findings open new pathways for large-scale, population-based health research by providing a promising, scalable, high-resolution method for characterising complex urban acoustic environments, supporting efforts to design healthier urban environments through higher acoustic quality.</p> SIGNIFICANCE <p>LUT-based models demonstrate their potential for predicting Link Density and LAeq, achieving moderate to strong performance across two independent test datasets. This can provide a scalable approach for investigating potentially health-relevant properties of the urban AE at high spatial resolution.</p>

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Modelling the urban acoustic environment using land use-based gradient boosting

  • Timo Haselhoff,
  • Susanne Moebus,
  • Mikel Jedrusiak,
  • Bryce T. Lawrence,
  • Frank Weichert

摘要

Background

Long-standing research on the relationship between the urban acoustic environment (AE) and human health demonstrates the harmful effects of environmental noise. Meanwhile, an increasing number of smaller studies report health benefits for additional acoustic properties. However, studies on health-promoting AEs remain limited, largely due to the lack of methods for estimating high-resolution acoustic properties beyond conventional noise metrics.

Objective

We investigate to what extent models based on land-use types (LUT) can predict urban AE properties, focusing on four acoustic indices (Articulation Index, Bioacoustic Index, Link Density and Sharpness). Additionally, we predict the LAeq, which enables us to compare the performance between our model, the strategic noise map of Bochum (SNM) and results from the literature.

Methods

We use a dataset of 2,746 acoustic measurements from 785 locations in Bochum and 90 measurements from 22 locations in Essen to train and evaluate gradient boosting models. For model development, data is split into training/validation (668 locations in Bochum) and test sets (117 locations in Bochum, all locations in Essen). The models predict acoustic indices based on the area of 77 LUTs within 50 and 300 m buffers around each location.

Results

Based on the root mean square error (RMSE), predictions for Link Density deviate on average by 0.17 and 0.21 from test-sets in Bochum and Essen. For LAeq, the RMSE is 4.8 dB(A) and 4.4 dB(A), respectively. The R2 for Link Density is between 0.27 and 0.3, and for the LAeq between 0.52 and 0.46. The SNM performs worse in predicting LAeq for Bochum data (RMSE = 7.8 dB(A); R2 = –0.31). Performances for other indices are mixed.

Impact

This study advances research on the urban acoustic environment by demonstrating that land use type-based models represent a promising approach to predict acoustic indices beyond conventional noise metrics. Using over 2,800 measurements from two German cities, the models for predicting the Link Density and the LAeq show moderate to good performance on two test datasets. Model predictions for the LAeq outperformed strategic noise maps in predicting total environmental noise. These findings open new pathways for large-scale, population-based health research by providing a promising, scalable, high-resolution method for characterising complex urban acoustic environments, supporting efforts to design healthier urban environments through higher acoustic quality.

SIGNIFICANCE

LUT-based models demonstrate their potential for predicting Link Density and LAeq, achieving moderate to strong performance across two independent test datasets. This can provide a scalable approach for investigating potentially health-relevant properties of the urban AE at high spatial resolution.