Automatic delineation of drainage basins from contour elevation data using skeleton construction techniques

Moretti, Giovanni; Orlandini, Stefano

doi:10.1029/2007wr006309

Cited by 27 publications

(41 citation statements)

References 20 publications

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“…When this technique is adopted, coarseresolution grids are no longer the essential elements upon which river network maps are based. Because drainage area elements can be defined independently of the coarseresolution grids, as done in smaller-scale hydrological models (e.g., Moore and Grayson, 1991;Goleti et al, 2008;Moretti and Orlandini, 2008), grid-based allocation of river networks, which underlies the FLOW method, is not the absolute way for describing global river network maps. Therefore, upscaling methods for deriving macro-scale river network maps have the potential to be further improved.…”

Section: Discussionmentioning

confidence: 99%

Deriving a global river network map and its sub-grid topographic characteristics from a fine-resolution flow direction map

Yamazaki

Oki

Kanae

2009

Hydrol. Earth Syst. Sci.

122

132

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Abstract. This paper proposes an improved method for converting a fine-resolution flow direction map into a coarseresolution river network map for use in global river routing models. The proposed method attempts to preserve the river network structure of an original fine-resolution map in the upscaling procedure, as this has not been achieved with previous upscaling methods. We describe an improved method in which a downstream cell can be flexibly located on any cell in the river network map. The improved method preserves the river network structure of the original flow direction map and allows automated construction of river network maps at any resolution. Automated construction of a river network map is helpful for attaching sub-grid topographic information, such as realistic river meanderings and drainage boundaries, onto the upscaled river network map. The advantages of the proposed method are expected to enhance the ability of global river routing models by providing ways to more precisely represent surface water storage and movement.

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Section: Discussionmentioning

confidence: 99%

Deriving a global river network map and its sub-grid topographic characteristics from a fine-resolution flow direction map

Yamazaki

Oki

Kanae

2009

Hydrol. Earth Syst. Sci.

122

132

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“…In fact, the contour-based models are particularly suitable for hydrological applications and other geophysical processes driven by gravity [26,48,37]. Flow nets derived from contour lines (CLs) can explicitly reproduce the way that water and sediments flow on the land surface [27]. In addition, for historical landscapes, contour elevation data remain the only available data source [12].…”

Section: Introductionmentioning

confidence: 99%

A robust channel network extraction method combining discrete curve evolution and the skeleton construction technique

Zheng

Xiong

Gong

et al. 2015

Advances in Water Resources

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“…However, although they have been further investigated for hydrological application (e.g. Dawes and Short, 1994;Maunder, 1999;Zhang et al, 1999;Moretti and Orlandini, 2008) contourbased DEMs come with some limitations. They have a relatively high data-storage demand, topographic attributes are complicated to derive, and they provide no computational advantages .…”

Section: Topography Representation In Computer Modelsmentioning

confidence: 99%

“…in terms of software to be used (e.g. O'Callaghan and Mark, 1984;Tarboton et al, 1991;Costa-Cabral and Burges, 1994;Lacroix et al, 2002;Vivoni et al, 2004;Moretti and Orlandini, 2008).…”

Section: Review Of Landscape Representation In Hydrological Modellingmentioning

confidence: 99%

lumpR 2.0.0: an R package facilitating landscape discretisation for hillslope-based hydrological models

2017

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Abstract. The characteristics of a landscape pose essential factors for hydrological processes. Therefore, an adequate representation of the landscape of a catchment in hydrological models is vital. However, many of such models exist differing, amongst others, in spatial concept and discretisation. The latter constitutes an essential pre-processing step, for which many different algorithms along with numerous software implementations exist. In that context, existing solutions are often model specific, commercial, or depend on commercial back-end software, and allow only a limited or no workflow automation at all.Consequently, a new package for the scientific software and scripting environment R, called lumpR, was developed. lumpR employs an algorithm for hillslope-based landscape discretisation directed to large-scale application via a hierarchical multi-scale approach. The package addresses existing limitations as it is free and open source, easily extendible to other hydrological models, and the workflow can be fully automated. Moreover, it is user-friendly as the direct coupling to a GIS allows for immediate visual inspection and manual adjustment. Sufficient control is furthermore retained via parameter specification and the option to include expert knowledge. Conversely, completely automatic operation also allows for extensive analysis of aspects related to landscape discretisation.In a case study, the application of the package is presented. A sensitivity analysis of the most important discretisation parameters demonstrates its efficient workflow automation. Considering multiple streamflow metrics, the employed model proved reasonably robust to the discretisation parameters. However, parameters determining the sizes of subbasins and hillslopes proved to be more important than the others, including the number of representative hillslopes, the number of attributes employed for the lumping algorithm, and the number of sub-discretisations of the representative hillslopes.

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Automatic delineation of drainage basins from contour elevation data using skeleton construction techniques

Cited by 27 publications

References 20 publications

Deriving a global river network map and its sub-grid topographic characteristics from a fine-resolution flow direction map

Deriving a global river network map and its sub-grid topographic characteristics from a fine-resolution flow direction map

A robust channel network extraction method combining discrete curve evolution and the skeleton construction technique

lumpR 2.0.0: an R package facilitating landscape discretisation for hillslope-based hydrological models

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