Abstract
By 2050, two-third of the world’s population will live in cities. In this study, we develop a framework for analyzing urban growth-related imperviousness in North Rhine-Westphalia (NRW) from the 1980s to date using Landsat data. For the baseline 2017-time step, official geodata was extracted to generate labelled data for ten classes, including three classes representing low, middle, and high level of imperviousness. We used the output of the 2017 classification and information based on radiometric bi-temporal change detection for retrospective classification. Besides spectral bands, we calculated several indices and various temporal composites, which were used as an input for Random Forest classification. The results provide information on three imperviousness classes with accuracies exceeding 75%. According to our results, the imperviousness areas grew continuously from 1985 to 2017, with a high imperviousness area growth of more than 167,000 ha, comprising around 30% increase. The information on the expansion of urban areas was integrated with population dynamics data to estimate the progress towards SDG 11. With the intensity analysis and the integration of population data, the spatial heterogeneity of urban expansion and population growth was analysed, showing that the urban expansion rates considerably excelled population growth rates in some regions in NRW. The study highlights the applicability of earth observation data for accurately quantifying spatio-temporal urban dynamics for sustainable urbanization and targeted planning.
Highlights
The objectives of this study are; first, to implement an automated retrospective classification approach for observing land use and imperviousness dynamics during the last 30 years; second, to analyze the spatial trends of urban sprawl in North Rhine-Westphalia (NRW), and; third to assess the intensity of densification and population dynamics to support the monitoring of SDG indicator 11.3.1
This study presents an approach for automated retrospective LU/LC classification with the use of the spectral information of unchanged pixels
The method’s performance indicates that it is a promising approach for quantifying the changes in land use, including the derivation of several levels of impervious surfaces, with the use of reference data only for the baseline timestep
Summary
Urbanization, which is caused by economic development and continuous population growth, as well as changing lifestyles, and residential and retail uses within the urban fringes is one of the most important drivers of terrestrial change [1,2]. As the global trend of urbanization is expected to further increase the urban share of the world population from about 55 percent in 2018 to 68 percent by 2050 [3], understanding transformations of urban areas, and navigating those transformations towards more sustainable path-ways is 4.0/). Growing urbanization makes urban areas highly dynamic [4], making the research on the detection of land-use patterns of great importance
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