Abstract
This study estimates the equivalent continuous sound pressure level (Leq) during peak daily periods (‘rush hour’) along the New Klang Valley Expressway (NKVE) in Shah Alam, Malaysia, using a land use regression (LUR) model based on machine learning, statistical regression, and geographical information systems (GIS). The research utilises two types of soft computing methods including machine learning (i.e., decision tree, random frost algorithms) and statistical regression (i.e., linear regression, support vector regression algorithms) to determine the best approach to create a prediction Leq map at the NKVE in Shah Alam, Malaysia. The selection of the best algorithm is accomplished by considering correlation, correlation coefficient, mean-absolute-error, mean-square-error, root-mean-square-error, and mean absolute percentage error. Traffic noise level was monitored using three sound level meters (TES 52A), and a traffic tally was done to analyse the traffic flow. Wind speed was gauged using a wind speed meter. The study relied on a variety of noise predictors including wind speed, digital elevation model, land use type (specifically, if it was residential, industrial, or natural reserve), residential density, road type (expressway, primary, and secondary) and traffic noise average (Leq). The above parameters were fed as inputs into the LUR model. Additional noise influencing factors such as traffic lights, intersections, road toll gates, gas stations, and public transportation infrastructures (bus stop and bus line) are also considered in this study. The models utilised parameters derived from LiDAR (Light Detection and Ranging) data, and various GIS (Geographical Information Systems) layers were extracted to produce the prediction maps. The results highlighted the superior performances by the machine learning (random forest) models compared to the statistical regression-based models.
Highlights
Urban population is continuously exposed to traffic noise [1]
This study aims to provide an objective summary of the key variables which exert a significant influence on how levels of traffic noise are defined as well as to analyse various soft computing techniques, commonly employed including decision trees (DT) [37], random forests (RF) [38], linear regression (LR) [39], and support vector regression (SVR) [40]
The findings showed how the traffic volume, road types, public transport, land use, digital surface model (DSM), and wind speed (WS) all had a significant impact on prediction of noise levels
Summary
Urban population is continuously exposed to traffic noise [1]. Road traffic is the most impacting noise source affecting human modern lifestyle [2]. The impacts of such noise on human health are well documented [3,4,5,6]. The World Health Organization (WHO) published a study based on the degree of exposure to traffic noise experienced by population in European cities. Results show that 50% of people suffered exposure to traffic noise of greater than 55 dB [12]. Studies have identified a strong correlation between traffic noise and the urban population [5,6]
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