Three-Dimensional Inundation Mapping Using UAV Image Segmentation and Digital Surface Model

Three-Dimensional Inundation Mapping Using UAV Image Segmentation and Digital Surface Model

Flood occurrence is increasing due to the expansion of urbanization and extreme weather like hurricanes; hence, research on methods of inundation monitoring and mapping has increased to reduce the severe impacts of flood disasters. This research studies and compares two methods for inundation depth...

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Bibliographic Details
Published in:ISPRS international journal of geo-information Vol. 10; no. 3; p. 144
Main Authors: Gebrehiwot, Asmamaw A, Hashemi-Beni, Leila
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-03-2021
Subjects:
3D inundation mapping
Accuracy
CNN
Data
Data acquisition
Deep learning
Digital imaging
Disasters
Extreme weather
Flood mapping
Flooded areas
Flooding
Floods
GFI
Hurricanes
Image processing
Image segmentation
LiDAR
Machine learning
Mapping
Neural networks
Polygons
remote sensing
Remote sensing systems
Rivers
SfM
Storm damage
Teaching methods
Three dimensional models
Topography
Unmanned aerial vehicles
Urbanization
Water depth
Water levels
Weather
United States > US
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Summary:Flood occurrence is increasing due to the expansion of urbanization and extreme weather like hurricanes; hence, research on methods of inundation monitoring and mapping has increased to reduce the severe impacts of flood disasters. This research studies and compares two methods for inundation depth estimation using UAV images and topographic data. The methods consist of three main stages: (1) extracting flooded areas and create 2D inundation polygons using deep learning; (2) reconstructing 3D water surface using the polygons and topographic data; and (3) deriving a water depth map using the 3D reconstructed water surface and a pre-flood DEM. The two methods are different at reconstructing the 3D water surface (stage 2). The first method uses structure from motion (SfM) for creating a point cloud of the area from overlapping UAV images, and the water polygons resulted from stage 1 is applied for water point cloud classification. While the second method reconstructs the water surface by intersecting the water polygons and a pre-flood DEM created using the pre-flood LiDAR data. We evaluate the proposed methods for inundation depth mapping over the Town of Princeville during a flooding event during Hurricane Matthew. The methods are compared and validated using the USGS gauge water level data acquired during the flood event. The RMSEs for water depth using the SfM method and integrated method based on deep learning and DEM were 0.34m and 0.26m, respectively.
ISSN:2220-9964
2220-9964
DOI:10.3390/ijgi10030144