Jiang, Ling Hu, Yang Xia, Xilin Liang, Qiuhua Soltoggio, Andrea Kabir, Syed A multi-scale mapping approach based on a deep learning CNN model for reconstructing high-resolution urban DEMs The scarcity of high-resolution urban digital elevation model (DEM) datasets, particularly in certain developing countries, has posed a challenge for many water-related applications such as flood risk management. A solution to address this is to develop effective approaches to reconstruct high-resolution DEMs from their low-resolution equivalents that are more widely available. However, the current high-resolution DEM reconstruction approaches mainly focus on natural topography. Few attempts have been made for urban topography, which is typically an integration of complex artificial and natural features. This study proposed a novel multi-scale mapping approach based on convolutional neural network (CNN) to deal with the complex features of urban topography and to reconstruct high-resolution urban DEMs. The proposed multi-scale CNN model was firstly trained using urban DEMs that contained topographic features at different resolutions, and then used to reconstruct the urban DEM at a specified (high) resolution from a low-resolution equivalent. A two-level accuracy assessment approach was also designed to evaluate the performance of the proposed urban DEM reconstruction method, in terms of numerical accuracy and morphological accuracy. The proposed DEM reconstruction approach was applied to a 121 km2 urbanized area in London, United Kingdom. Compared with other commonly used methods, the current CNN-based approach produced superior results, providing a cost-effective innovative method to acquire high-resolution DEMs in other data-scarce regions. Urban DEM;High resolution;Deep learning;Convolutional neural network;Multiple scales;Flood modeling 2020-05-13
    https://repository.lboro.ac.uk/articles/journal_contribution/A_multi-scale_mapping_approach_based_on_a_deep_learning_CNN_model_for_reconstructing_high-resolution_urban_DEMs/12292784