Abstract
High-resolution DEMs are important spatial data, and are used in a wide range of analyses and applications. However, the high cost to obtain high-resolution DEM data over a large area through sensors with higher precision poses a challenge for many geographic analysis applications. Inspired by the convolution neural network (CNN) excellent performance in super-resolution (SR) image analysis, this paper investigates the use of deep residual neural networks and low-resolution DEMs to generate high-resolution DEMs. An enhanced double-filter deep residual neural network (EDEM-SR) method is proposed, which uses filters with different receptive field sizes to fuse and extract features and reconstruct a more realistic high-resolution DEM. The results were compared with those generated with the bicubic, bilinear, and EDSR methods. The numerical accuracy and terrain feature preserving effects of the EDEM-SR method can generate reconstructed DEMs that better match the original DEMs, show lower MAE and RMSE, and improve the accuracy of the terrain parameters. MAE is reduced by about 30 to 50% compared with traditional interpolation methods. The results show how the EDEM-SR method can generate high-resolution DEMs using low-resolution DEMs.
Highlights
IntroductionWith the increasing use of DEMs in many fields, such as 3D terrain visualization, hydrological, ecological, and geomorphological analysis [1,2,3,4], it is necessary to obtain high resolution DEMs for large areas
An EDEM-SR method with double filters was proposed for superresolution DEM reconstruction
Comparing the accuracy of the high-resolution DEMs reconstructed by different methods, the EDEM-SR
Summary
With the increasing use of DEMs in many fields, such as 3D terrain visualization, hydrological, ecological, and geomorphological analysis [1,2,3,4], it is necessary to obtain high resolution DEMs for large areas. A high-resolution DEM contains more information and can better reflect the actual surface, which plays a crucial role in the correct derivation of terrain factors such as slope, aspect, and the topographic wetness index [5,6]. It is difficult to obtain large-scale high-resolution DEMs using sensors with high precision. There are some open-access low-resolution DEMs with global coverage, including SRTM and ASTER GDEM.
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