How to evaluate the quality of coarse‐resolution DEM‐derived drainage networks

Sousa, Thâmara Martins Ismael de; Paz, Adriano Rolim da

doi:10.1002/hyp.11262

Cited by 11 publications

(4 citation statements)

References 118 publications

(261 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the next step, gIS hydrological analysis was performed using DEm data with a precision of 3.0 m downloaded from the NOaa website to establish an overall understanding of the basic hydrological characteristics of the peninsula. Digital elevation models (DEm) are widely used in various environmental studies and are commonly used to obtain information on flow directions, flow accumulation, drainage networks, and watershed partitioning [12]. hydrologic analysis tools in aRcgIS software are used to carry out filling analysis, define flow direction, capture river network outlets, extract flow network and flow network classification, etc.…”

Section: Peninsula Hydrologic Analysis and Basin Divisionmentioning

confidence: 99%

Research on design method for the blue-green ecological network system to deal with urban flooding: A case study of Charleston Peninsula

Liang¹,

Hewitt²,

Yan³

2019

Int. J. DNE

View full text Add to dashboard Cite

1 key laboratory of urban agriculture in central china, ministry of agriculture and Rural affairs, huazhong agricultural university, china. 2 clemson university, united States of america.aBSTRacT The landscape strategy to deal with climate change has become an important issue in the process of sustainable urban development in the world. Particular focus is given to the charleston Peninsula in South carolina, uSa, which faces floods due to inefficiency in stormwater collection systems, increased frequency of intense rain events, excessive impervious surfaces, tide cycles, etc. In addition, hurricane events and sea-level rise are considered sources of flood risk in the coastal areas of the peninsula. This research draws on existing urban stormwater management theory to argue that the blue and green water ecological network system in the built-up area represents an innovative approach to alleviate flooding and promote a healthy landscape during urban renewal. according to the analysis of hydrological characteristics, the peninsula is divided into 17 basins, and then each basin is studied separately. Within Basin 8, the potential block is divided into four types of functional stormwater management units (fast flow zone, absorption containment zone, additional digestion zone, and upstream interception zone) and connected by a reintegrated drainage system. finally, the corresponding micro-landscape strategy is proposed according to the block property. functional units simultaneously undertake the functions of rainwater management and landscape activities. In the end, the new active-recreation space and passive-recreation space in the network are connected with the original urban green space and provide the city with a series of unique ecosystem services to support urban drainage systems and human health. It is hoped this research will provide an attempt for future urban stormwater management from the perspective of landscape planning and design.

show abstract

Section: Peninsula Hydrologic Analysis and Basin Divisionmentioning

confidence: 99%

Research on design method for the blue-green ecological network system to deal with urban flooding: A case study of Charleston Peninsula

Liang¹,

Hewitt²,

Yan³

2019

Int. J. DNE

View full text Add to dashboard Cite

show abstract

“…So, the extraction of drainage channels relies not on the isolated elevation sampling points but on the spatial relationship between these points (Vaze et al, 2010). However, traditional researches have regarded data source, resolution and interpolation method as main factors to measure the extraction accuracy (Sousa et al, 2017;Ariza-Villaverde et al, 2015;Woodrow et al, 2016). They ignore the impact of different shape of regular grid on terrain surface representation of DEM, which plays a role in results of streaming extraction.…”

Section: Intruductionmentioning

confidence: 99%

The Comparison of Drainage Network Extraction Between Square and Hexagonal Grid-Based Dem

Wang

2018

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

View full text Add to dashboard Cite

Abstract. The automatic extraction of valleys or ridges from DEM is a long term topic in the GIS and hydrology fields and a number of algorithms have been developed. The quality of drainage networks extraction depends on many impacts such as data source, DEM resolution and extraction algorithms. However, little consideration has been paid to the influence of different tessellation of grid-based DEM construction in terrain surface representation. Actually, hexagonal grid has been proved to be advantageous over square grid due to its consistent connectivity, isotropy of local neighbourhoods, higher symmetry, visual advantage, and so on. This study tries to explore the impact of different tessellation scheme for grid-based DEM on the accuracy of terrain representation reflected by the results of drainage networks extraction. The contour line data model is applied to grid-based DEM generation. Then, by analogy with traditional D8 algorithm, the D6 algorithm is introduced to extract drainage networks by calculating flow direction of each gird with the steepest slope neighbour criteria. From the comparison between D8 algorithm and D6 algorithm, we conclude that hexagonal grid-based DEM has a superior capability in maintaining the detailed shape and the characteristics of extracted drainage networks in coarser resolution.

show abstract

“…Visual inspection at the outlet of the catchment confirms that the amount and density of streams decreased, but the major rivers in the generated stream network were still consistent with the known river network (Figure 41 and Figure 42). There are techniques for comparing the DEM-derived stream network with a reference network: comparing the drainage densities, lumped basin characteristics, delineated watersheds, prediction of channel heads, and visual inspection (Sousa & Paz, 2017). To compare the derived stream network with the reference network in CDO, the percentage within buffer (PWB) comparison was used: a buffer is added to the reference stream network and the percentage of DEM-derived stream cells that fall within that buffer is counted (Davies & Bell, 2009).…”

Section: Parameters That Influence the Stream Networkmentioning

confidence: 99%

Understanding the effect of changing land use on floods and soil erosion in the Cagayan de Oro catchment

Benavidez¹

View full text Add to dashboard Cite

The destructive capability of typhoons affects lives and infrastructure around the world. Spatial analysis of historical typhoon records reveal an area of intense storm activity within the Southeast Asian (SEA) region. Within SEA is the Philippines, an archipelagic tropical country regularly struck by storms that often cause severe landslides, erosion and floods. Annually, ˜20 cyclones enter the Philippine Area of Responsibility, with about nine making landfall, causing high winds and intense rainfall. Thus, significant research in the Philippines has focused on increasing the resilience of ecosystems and communities through real-time disaster forecasting, structural protections, and programmes for sustainable watershed management (e.g. rehabilitation and conservation agriculture). This dissertation focused on the third aspect through computer modelling and scenario analysis. The study area is the Cagayan de Oro (CDO) catchment (˜1400km²) located in the Southern Philippines. The catchment experienced heavy flooding in 2012 from Typhoon Bopha and has major erosion problems due to mountainous slopes and heavy rainfall. Communities derive ecosystem services (ES) including agricultural production, water supply, recreation, mining resources, flood mitigation, etc. Since changes to the supply or distribution of these ES affects livelihoods and the hydrological response of the catchment to typhoon events, this research used the Land Utilisation and Capability Indicator (LUCI) model to understand the baseline ES and potential changes associated with basin management plans. This was the first detailed tropical application of LUCI, including parameterising it for Philippine soil and land cover datasets in CDO and extending its capability to be applied in future tropical areas. Aside from applying LUCI in a new geoclimatic region, this research contributed to the general development of LUCI through testing and improving its sediment delivery and inundation modelling. The sediment delivery was enhanced using the Revised Universal Soil Loss Equation (RUSLE) model that allows LUCI for the first time to account for impacts of specific land management such as agroforestry and contour cropping on erosion and sediment delivery. Progress was made in updating a flatwater inundation model for use with LUCI, including converting it to Python but this requires further development and testing before it is suitable for application in the Philippines. The development and rehabilitation scenarios showed improved flood mitigation, lower surficial soil erosion rates, and lower loads of nutrients compared to the baseline scenario. Additionally, ES mapping under different land cover scenarios has not been previously accomplished in CDO, and this research provides useful information to guide local decision-making and management planning. The rainfall-runoff model of LUCI was tested against the Hydrologic Engineering Center’s Hydrological Modelling System (HEC-HMS), showing good agreement with observed flow. Since the rainfall-runoff model of LUCI has been minimally utilised in past applications, this CDO application elucidated directions for future work around further testing under extreme rainfall events and climate change. Overall, this novel application of LUCI creates a framework to assist decision-making around land cover changes in the CDO, provides guidance around data requirements and parameterisation procedures to guide future international applications, and has significantly contributed to development and improvement of the LUCI framework to extend its modelling capabilities in the future.

show abstract

How to evaluate the quality of coarse‐resolution DEM‐derived drainage networks

Cited by 11 publications

References 118 publications

Research on design method for the blue-green ecological network system to deal with urban flooding: A case study of Charleston Peninsula

Research on design method for the blue-green ecological network system to deal with urban flooding: A case study of Charleston Peninsula

The Comparison of Drainage Network Extraction Between Square and Hexagonal Grid-Based Dem

Understanding the effect of changing land use on floods and soil erosion in the Cagayan de Oro catchment

Contact Info

Product

Resources

About