Evaluation of Various Resolution DEMs in Flood Risk Assessment and Practical Rules for Flood Mapping in Data-Scarce Geospatial Areas: A Case Study in Thessaly, Greece

Xafoulis, Nikolaos; Kontos, Yiannis; Farsirotou, Evangelia; Kotsopoulos, Spyridon; Perifanos, Konstantinos; Alamanis, Nikolaos; Dedousis, Dimitrios; Katsifarakis, Konstantinos

doi:10.3390/hydrology10040091

Cited by 13 publications

(8 citation statements)

References 23 publications

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“…More prevalent is the use of scale transfers via coarse hydrodynamic models, where the friction term is calibrated to observations yielding coarse WSH grids directly from aggregated or coarse DEM grids. Such scaling issues in coarse hydrodynamic models have been studied extensively (Banks et al., 2015; Ghimire & Sharma, 2021; Mohanty et al., 2020; Muthusamy et al., 2021; Saksena & Merwade, 2015; Xafoulis et al., 2023). To evaluate the transferability between the aggregation routines considered here and hydrodynamic modeling (i.e., whether aggregation behavior might serve as an analog for coarse hydrodynamic modeling behavior) Text S3 in Supporting Information presents a brief comparison of the aggregation routines against a depth calibrated hydrodynamic model built on a DEM resampled to the coarse resolution ( s 2 = 32 m) for a separate case study where more data is available.…”

Section: Computational Results and Discussionmentioning

confidence: 99%

“…Because of the computational demands of such models, resolution has been extensively studied and found to be one of the parameters of most importance for accuracy (Alipour et al., 2022; Fewtrell et al., 2008; Papaioannou et al., 2016; Savage et al., 2016). Focusing on the relationship between model resolution and inundation area, many studies of fluvial floods find a positive inundation area and flood depth bias at coarser resolutions (Banks et al., 2015; Ghimire & Sharma, 2021; Mohanty et al., 2020; Muthusamy et al., 2021; Saksena & Merwade, 2015; Xafoulis et al., 2023) while studies of urban flooding are less conclusive (Fewtrell et al., 2008). For the underlying terrain model grids or digital elevation models (DEM), the resampling method used to generate the coarse analogs is often found to be of little significance (Muthusamy et al., 2021; Saksena & Merwade, 2015) except at high resolutions when buildings are present in the fine DEM (Fewtrell et al., 2008).…”

Section: Introductionmentioning

confidence: 99%

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Bias in Flood Hazard Grid Aggregation

Bryant,

Kreibich,

Merz

2023

Water Resources Research

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Reducing flood risk through disaster planning and risk management requires accurate estimates of exposure, damage, casualties, and environmental impacts. Models can provide such information; however, computational or data constraints often lead to the construction of such models by aggregating high‐resolution flood hazard grids to a coarser resolution, the effect of which is poorly understood. Through the application of a novel spatial classification framework, we derive closed‐form solutions for the location (e.g., flood margins) and direction of bias from flood grid aggregation independent of any study region. These solutions show bias of some key metric will always be present in regions with marginal inundation; for example, inundation area will be positively biased when water depth grids are aggregated and volume will be negatively biased when water surface elevation grids are aggregated through averaging. In a separate computational analysis, we employ the same framework to a 2018 flood and successfully reproduce the findings of our study‐region‐independent derivation. Extending the investigation to the exposure of buildings, we find regions with marginal inundation are an order of magnitude more sensitive to aggregation errors, highlighting the importance of understanding such artifacts for flood risk modellers. Of the two aggregation routines considered, averaging water surface elevation grids better preserved flood depths at buildings than averaging of water depth grids. This work provides insight into, and recommendations for, aggregating grids used by flood risk models.This article is protected by copyright. All rights reserved.

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Section: Computational Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bias in Flood Hazard Grid Aggregation

Bryant,

Kreibich,

Merz

2023

Water Resources Research

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“…The paper "Evaluation of Various Resolution DEMs in Flood Risk Assessment and Practical Rules for Flood Mapping in Data-Scarce Geospatial Areas: A Case Study in Thessaly, Greece" [12] by Nikolaos Xafoulis, Yiannis Kontos, Evangelia Farsirotou, Spyridon Kotsopoulos, Konstantinos Perifanos, Nikolaos Alamanis, Dimitrios Dedousis and Konstantinos Katsifarakis investigated flood modelling sensitivity against geospatial data accuracy using the following DTM resolutions in a mountainous river sub-basin of Thessaly's Water District (Greece): (a) open 5 m and (b) 2 m data from Hellenic Cadastre (HC) and (c) 0.05 m data from a topographical mission using an unmanned aerial vehicle (UAV). RAS-Mapper and HEC-RAS were used for 1D (steady state) hydraulic simulation regarding a 1000-year return period.…”

Section: Contributed Papersmentioning

confidence: 99%

Modern Developments in Flood Modelling

Tegos

Ziogas²,

Bellos

2023

Hydrology

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“…Despite hydrological models having recently made great progress in mapping water pathways during flood events [2][3][4], accurately modeling the evolution of floods on the ground in urban areas at the temporal and spatial scales, requiring resolving single-home or finer spatial scale issues, is still problematic. The discharge of water depends, indeed, on many endogenous (e.g., fluid properties) and exogenous (e.g., street material, roughness, slope, etc.)…”

Section: Introductionmentioning

confidence: 99%

Assessment of a Machine Learning Algorithm Using Web Images for Flood Detection and Water Level Estimates

Tedesco,

Radzikowski

2023

GeoHazards

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Improving our skills to monitor flooding events is crucial for protecting populations and infrastructures and for planning mitigation and adaptation strategies. Despite recent advancements, hydrological models and remote sensing tools are not always useful for mapping flooding at the required spatial and temporal resolutions because of intrinsic model limitations and remote sensing data. In this regard, images collected by web cameras can be used to provide estimates of water levels during flooding or the presence/absence of water within a scene. Here, we report the results of an assessment of an algorithm which uses web camera images to estimate water levels and detect the presence of water during flooding events. The core of the algorithm is based on a combination of deep convolutional neural networks (D-CNNs) and image segmentation. We assessed the outputs of the algorithm in two ways: first, we compared estimates of time series of water levels obtained from the algorithm with those measured by collocated tide gauges and second, we performed a qualitative assessment of the algorithm to detect the presence of flooding from images obtained from the web under different illumination and weather conditions and with low spatial or spectral resolutions. The comparison between measured and camera-estimated water levels pointed to a coefficient of determination R2 of 0.84–0.87, a maximum absolute bias of 2.44–3.04 cm and a slope ranging between 1.089 and 1.103 in the two cases here considered. Our analysis of the histogram of the differences between gauge-measured and camera-estimated water levels indicated mean differences of −1.18 cm and 5.35 cm for the two gauges, respectively, with standard deviations ranging between 4.94 and 12.03 cm. Our analysis of the performances of the algorithm to detect water from images obtained from the web and containing scenes of areas before and after a flooding event shows that the accuracy of the algorithm exceeded ~90%, with the Intersection over Union (IoU) and the boundary F1 score (both used to assess the output of segmentation analysis) exceeding ~80% (IoU) and 70% (BF1).

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Evaluation of Various Resolution DEMs in Flood Risk Assessment and Practical Rules for Flood Mapping in Data-Scarce Geospatial Areas: A Case Study in Thessaly, Greece

Cited by 13 publications

References 23 publications

Bias in Flood Hazard Grid Aggregation

Bias in Flood Hazard Grid Aggregation

Modern Developments in Flood Modelling

Assessment of a Machine Learning Algorithm Using Web Images for Flood Detection and Water Level Estimates

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