Fusion of multi-scale DEMs using a regularized super-resolution method

Yue, Linwei; Shen, Huanfeng; Yuan, Qiangqiang; Zhang, Liangpei

doi:10.1080/13658816.2015.1063639

Cited by 31 publications

(20 citation statements)

References 46 publications

(56 reference statements)

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“…To address inhomogenity of available DEM products, several methods of fusing DEMs have been developed to obtain a complete DEM coverage with improved quality. Fusion approaches vary from simple techniques, such as weighted averaging of input DEMs based on height error maps [3], or terrain derivatives [4,5], to more complex techniques involving the use of sparse representations [6], frequency domain filtering [7], slope-based Markov random field regularization [8], or k-means clustering [9].…”

Section: Introductionmentioning

confidence: 99%

Fusion of high-resolution DEMs for water flow modeling

Petrášová

Mitášová

Petras

et al. 2017

Open geospatial data, softw. stand.

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Background: New technologies for terrain reconstruction have increased the availability of topographic data at a broad range of resolutions and spatial extents. The existing digital elevation models (DEMs) can now be updated at a low cost in selected study areas with newer, often higher resolution data using unmanned aerial systems (UAS) or terrestrial sensors. However, differences in spatial coverage and levels of detail often create discontinuities along the newly mapped area boundaries and subsequently lead to artifacts in results of DEM analyses or models of landscape processes. Methods: To generate a seamless updated DEM, we propose a generalized approach to DEM fusion with a smooth transition while preserving important topographic features. The transition is controlled by distance-based weighted averaging along the DEMs' blending overlap with spatially variable width based on elevation differences. Results: We demonstrate the method on two case studies exploring the effects of DEM fusion on water flow modeling in the context of precision agriculture. In the first case study, we update a lidar-based DEM with a fused set of two digital surface models (DSMs) derived from imagery acquired by UAS. In the second application, developed for a tangible geospatial interface, we fuse a georeferenced, physical sand model continuously scanned by a Kinect sensor with a lidar-based DEM of the surrounding watershed in order to computationally simulate and test methods for controlling storm water flow. Conclusions:The results of our experiments demonstrate the importance of seamless, robust fusion for realistic simulation of water flow patterns using multiple high-resolution DEMs.

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Section: Introductionmentioning

confidence: 99%

Fusion of high-resolution DEMs for water flow modeling

Petrášová

Mitášová

Petras

et al. 2017

Open geospatial data, softw. stand.

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“…For SRTM1 data beyond the 50° latitude, the tiles are sampled at 2 arc-seconds along the longitudinal direction. To ensure the spatial consistency of the global data, we used the multi-scale data fusion method [26] to up-sample the high-latitude data between 50° and 60° to 1-arc×1-arc tiles. To reconstruct the high-latitude SRTM tiles, the input data include the original SRTM1 and the high-resolution ASTER GDEM and AW3D30 data.…”

Section: Multi-scale Fusion For the High-latitude Tilesmentioning

confidence: 99%

“…A is the multiplication of the translation matrix k M , the sampling matrix k D and the cropping matrix k O , which can be described as k [26]. Besides, k n stands for the additive noises in the input DEMs, also including the model errors.…”

Section: Multi-scale Fusion For the High-latitude Tilesmentioning

confidence: 99%

“…The second term is the regularization prior used to describe the spatial characteristics of the fused data. Here we employ the adaptive Markov-random field regularization to model the contextual correlations between neighboring elevation pixels [26]. For   c d  in equation (1), the finite-difference approximations to second-order derivatives in four directions ( =4  ) are employed to measure the spatial relationship between the neighboring pixels [50].…”

Section: Multi-scale Fusion For the High-latitude Tilesmentioning

confidence: 99%

“…Based on the fusion methods, great efforts have been made to generate high-quality DEM products by merging the existing datasets [19,21,25].In this paper, we introduce a fused DEM dataset (82°S-82°N) mainly reconstructed from the 30-m unfilled SRTM1, AW3D30, ASTER GDEM v2 and ICESat GLAS data, which we refer to as GSDEM-30. The goal is to generate a global seamless DEM using the multi-source accuracy enhancement method and the regularized multi-scale fusion algorithm [22,26]. Considering the global data characteristics, the artificial neural network (ANN) based accuracy enhancement and void filling method were used for the void SRTM tiles between 50°S-50°N, while the multi-scale fusion algorithm was applied to the SRTM tiles sub-sampled to a 2-arc-second resolution along the longitude within 50-60°N and 50°-60°S.…”

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confidence: 99%

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A Global Seamless DEM Based on Multi-Source Data Fusion (GSDEM-30): Product Generation and Evaluation

L¹,

Shen²,

Liu³

et al. 2019

Preprint

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The quality of digital elevation models (DEMs) is inevitably affected by the limitations of the imaging modes and the generation methods. One effective way to solve this problem is to merge the available datasets through data fusion. In this paper, a fusion-based global DEM dataset (82°S-82°N) is introduced, which we refer to as GSDEM-30. This is a 30-m DEM mainly reconstructed from the unfilled SRTM1, AW3D30, and ASTER GDEM v2 datasets combining the multi-source and multi-scale fusion techniques. A comprehensive evaluation of the GSDEM-30 data, as well as the 30-m ASTER GDEM v2 and AW3D30 DEM, was presented. Global ICESat GLAS data and the local National Elevation Dataset (NED) were used as the reference for the vertical accuracy validation, while GlobeLand30 was introduced for the landscape analysis. Furthermore, we employed the maximum slope approach to detect the potential artefacts in the DEMs. The results show that the GDEM data are seriously affected by noise and artefacts. With the advantage of the multiple datasets and the refined post-processing, the GSDEM-30 are contaminated with fewer anomalies than both ASTER GDEM and AW3D30. The fusion techniques used can also be applied to the reconstruction of other fused DEM datasets.interferometric signal and stereo images, as well as the post-processing methods, will affect the data accuracy [10].Consequently, the tradeoff between the spatial resolution, spatial coverage, and vertical accuracy means that the currently available datasets do not meet the demands for the large-scale geospatial applications [11]. On the one hand, more advanced imaging and processing technologies will be applied to Earth observation [12], and new products with a higher resolution and fine-edited quality are being generated and released. However, new data generation is not only highly cost and time-consuming, but is also inevitably limited by the imaging techniques [13]. Moreover, the editing of raw DEM data only using the single-source information, e.g. the noise filtering and voids interpolation methods, might fail in the cases where local data quality are poor [14][15][16][17][18]. Thus, considering the auxiliary information among the multi-source datasets, merging the currently available datasets through multi-source data fusion is a possible way to solve this problem. Different fusion techniques were developed to solve the quality issues of DEM data, such as voids, anomalies and different sources of noise [14,[19][20][21][22][23][24]. Based on the fusion methods, great efforts have been made to generate high-quality DEM products by merging the existing datasets [19,21,25].In this paper, we introduce a fused DEM dataset (82°S-82°N) mainly reconstructed from the 30-m unfilled SRTM1, AW3D30, ASTER GDEM v2 and ICESat GLAS data, which we refer to as GSDEM-30. The goal is to generate a global seamless DEM using the multi-source accuracy enhancement method and the regularized multi-scale fusion algorithm [22,26]. Considering the global data characteristics, the artificial neural networ...

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A scoping review on the multiplicity of scale in spatial analysis

et al. 2022

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Scale is a central concept in the geographical sciences and is an intrinsic property of many spatial systems. It also serves as an essential thread in the fabric of many other physical and social sciences, which has contributed to the use of different terminology for similar manifestations of what we refer to as ‘scale’, leading to a surprising amount of diversity around this fundamental concept and its various ‘multiscale’ extensions. To address this, we review common abstractions about spatial scale and how they are employed in quantitative research. We also explore areas where the conceptualizations of multiple spatial scales can be differentiated. This is achieved by first bridging terminology and concepts, and then conducting a scoping review of the topic. A typology for spatial scale is discussed that can be used to categorize its multifarious meanings and measures. This typology is then used to distinguish what we term ‘process scale,’ from other types of spatial scale and to highlight current trends in uncovering aspects of process scale. We end with suggestions on how to further build knowledge regarding spatial processes through the lens of spatial scale.

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Fusion of multi-scale DEMs using a regularized super-resolution method

Cited by 31 publications

References 46 publications

Fusion of high-resolution DEMs for water flow modeling

Fusion of high-resolution DEMs for water flow modeling

A Global Seamless DEM Based on Multi-Source Data Fusion (GSDEM-30): Product Generation and Evaluation

A scoping review on the multiplicity of scale in spatial analysis

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