Abstract
In the last decades, urban climate researchers have highlighted the need for a reliable provision of meteorological data in the local urban context. Several efforts have been made in this direction using Artificial Neural Networks (ANN), demonstrating that they are an accurate alternative to numerical approaches when modelling large time series. However, existing approaches are varied, and it is unclear how much data are needed to train them. This study explores whether the need for training data can be reduced without overly compromising model accuracy, and if model reliability can be increased by selecting the UHI intensity as the main model output instead of air temperature. These two approaches were compared using a common ANN configuration and under different data availability scenarios. Results show that reducing the training dataset from 12 to 9 or even 6 months would still produce reliable results, particularly if the UHI intensity is used. The latter proved to be more effective than the temperature approach under most training scenarios, with an average RMSE improvement of 16.4% when using only 3 months of data. These findings have important implications for urban climate research as they can potentially reduce the duration and cost of field measurement campaigns.
Highlights
Published: 21 July 2021In the context of raising awareness on climate change, a good understanding of urban climate phenomena is a key milestone in order to mitigate and adapt to thermal extremes within urban environments [1,2]
The present study focuses on the city of Madrid
We use the hourly, dry-bulb temperature gathered at the city centre (Embajadores, see Figure 1), classified as compact midrise (LCZ 2) according to the Local Climate Zones (LCZ) scheme [98], and which registered the highest mean and nighttime UHI intensity
Summary
Published: 21 July 2021In the context of raising awareness on climate change, a good understanding of urban climate phenomena is a key milestone in order to mitigate and adapt to thermal extremes within urban environments [1,2]. Cities are one of the main contributors to the greenhouse effect [3], and places where many inequalities and potential vulnerabilities accumulate [4,5,6]. Recent studies, such as those developed by Grimm et al [7] and Youngsteadt [8], suggest that cities could provide important insights into the socio-ecological dynamics of our near future at a global scale, increasing the interest for reliable urban climatic data and expanding its applications to many other disciplines.
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