Improving Low-Relief Coastal LiDAR DEMs with Hydro-Conditioning of Fine-Scale and Artificial Drainages
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Date
2015-11-23
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Authors
Allen, Thomas Richard
Howard, Robert
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Abstract
Improvements in Light Detection and Ranging (LiDAR) technology and spatial analysis
of high-resolution digital elevation models (DEMs) have advanced the accuracy and
diversity of applications for coastal hazards and natural resources management.
This article presents a concise synthesis of LiDAR analysis for coastal flooding and
management applications in low-relief coastal plains and a case study demonstration of
a new, efficient drainage mapping algorithm. The impetus for these LiDAR applications
follows historic flooding from Hurricane Floyd in 1999, after which the State of North
Carolina and the Federal Emergency Management Agency (FEMA) undertook extensive
LiDAR data acquisition and technological developments for high-resolution floodplain
mapping. An efficient algorithm is outlined for hydro-conditioning bare earth (BE) LiDAR
DEMs using available US Geological Survey1 National Hydrography Dataset (NHD)
canal and ditch vectors. The methodology is illustrated in Moyock, North Carolina,
for refinement of hydro-conditioning by combining pre-existing BE DEMs with spatial
analysis of LiDAR point clouds in segmented and buffered ditch and canal networks. The
methodology produces improved maps of fine-scale drainage, reduced omission of areal
flood inundation, and subwatershed delineations that typify heavily ditched and canalled
drainage areas. These preliminary results illustrate the capability of the technique to
improve the representation of ditches in DEMs as well as subsequent flow and inundation
modeling that could spur further research on low-relief coastal LiDAR applications.
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DOI
10.3389/feart.2015.00072