Understanding Uncertainty in Probabilistic Floodplain Mapping in the Time of Climate Change

Zahmatkesh, Zahra; Han, Shasha; Coulibaly, Paulin

doi:10.3390/w13091248

Cited by 9 publications

(13 citation statements)

References 80 publications

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“…Parameters' distributions can be obtained using nominal probability models from expert's knowledge (Kalyanapu et al., 2012; Stephens & Bledsoe, 2020) or statistically calibrated ones generally via the GLUE methodology (G. T. Aronica et al., 2012; Di Baldassarre et al., 2010; Kiczko et al., 2013; Romanowicz & Kiczko, 2016; Zahmatkesh et al., 2021). In this work, epistemic uncertainty will be represented by probability distributions in the roughness parameters only, for the floodplain and for the channel, considering all other parameters, such as DEM or channel bathymetry, as constant regarding the calibration procedure.…”

Section: Methodsmentioning

confidence: 99%

“…That is, defining a distribution for the uncertain discharge for a given return period. This includes accounting for statistical fitting errors due to limited‐length data and distribution family (Apel et al., 2008; G. T. Aronica et al., 2012; Neal et al., 2013; Romanowicz & Kiczko, 2016; Stephens & Bledsoe, 2020; Winter et al., 2018), additional forcing variables such as flood volume (Candela & Aronica, 2017) or sea‐level rise (Muñoz et al., 2022), or more general hydrograph shape uncertainties through hydrological modeling (Ahmadisharaf et al., 2018; Falter et al., 2015; Grimaldi et al., 2013; Meresa et al., 2021; Zahmatkesh et al., 2021). Others have focused on including uncertainty in the inundation model through its most sensitive parameters such as roughness coefficients (G. T. Aronica et al., 2012; Bharath & Elshorbagy, 2018; Di Baldassarre et al., 2010; Kalyanapu et al., 2012; Kiczko et al., 2013; Romanowicz & Kiczko, 2016), Digital Elevation Maps (DEM) (Apel et al., 2008), or cross‐section geometrical properties (Stephens & Bledsoe, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Others have focused on including uncertainty in the inundation model through its most sensitive parameters such as roughness coefficients (G. T. Aronica et al., 2012; Bharath & Elshorbagy, 2018; Di Baldassarre et al., 2010; Kalyanapu et al., 2012; Kiczko et al., 2013; Romanowicz & Kiczko, 2016), Digital Elevation Maps (DEM) (Apel et al., 2008), or cross‐section geometrical properties (Stephens & Bledsoe, 2020). Furthermore, many of these have included both the epistemic uncertainties in the discharges recurrence as well as in the inundation model (Apel et al., 2008; G. T. Aronica et al., 2012; Bharath & Elshorbagy, 2018; Di Baldassarre et al., 2010; Kalyanapu et al., 2012; Kiczko et al., 2013; Romanowicz & Kiczko, 2016; Stephens & Bledsoe, 2020; Zahmatkesh et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

“…This review of the literature on uncertainty quantification in flood hazard assessments shows that epistemic uncertainties are always kept separate from aleatory uncertainty. As a result, the hazard output is always in the form of a distribution of the probability of exceeding an IM level; whether it is given as a “probability of flood map” for different return periods (Bharath & Elshorbagy, 2018; Di Baldassarre et al., 2010; Domeneghetti et al., 2013; Kiczko et al., 2013; Neal et al., 2013; Stephens & Bledsoe, 2020; Zahmatkesh et al., 2021), or as confidence intervals of IM exceedance curves for each point in space (G. T. Aronica et al., 2012; Nuswantoro et al., 2016; Romanowicz & Kiczko, 2016). While this separation is useful to identify ways of reducing uncertainty, it has been shown to be challenging for proper communication and interpretation, even leading to inconsistent decision making (Der Kiureghian & Ditlevsen, 2009; Fawcett & Green, 2018; Fenton & Neil, 2013; Fox & Ülkümen, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…The typical outcome from most of these approaches is in the form of "probability of flood" maps for different return periods. That is, for a specific return period, different forcing events and/or inundation model parameters are randomly sampled and used to obtain an ensemble of flood maps from which the probability of flooding is computed empirically (Bharath & Elshorbagy, 2018;Di Baldassarre et al, 2010;Domeneghetti et al, 2013;Kiczko et al, 2013;Neal et al, 2013;Stephens & Bledsoe, 2020;Zahmatkesh et al, 2021). However, a flood risk analysis requires estimating potential damages from the hazard outcomes, and this type of input is not very helpful since most flood damage models use as input the water depth above ground level (and eventually flow velocity and flood duration) (Galasso et al, 2021;Mohanty et al, 2020;Nofal & Van De Lindt, 2022;Pregnolato et al, 2015).…”

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confidence: 99%

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The Cost of Imperfect Knowledge: How Epistemic Uncertainties Influence Flood Hazard Assessments

Balbi,

Lallemant

2023

Water Resources Research

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Classical approaches to flood hazard are obtained by the concatenation of a recurrence model for the events (i.e., an extreme river discharge) and an inundation model that propagates the discharge into a flood extent. The classical approach, however, uses “best‐fit” models that do not include uncertainty from incomplete knowledge or limited data availability. The inclusion of these, so called epistemic uncertainties, can significantly impact flood hazard estimates and the corresponding decision‐making process. We propose a simulation approach to robustly account for uncertainty in model's parameters, while developing a useful probabilistic output of flood hazard for further risk assessments via the Bayesian predictive posterior distribution of water depths. A Peaks‐Over‐Threshold Bayesian analysis is performed for future events simulation, and a pseudo‐likelihood probabilistic approach for the calibration of the inundation model is used to compute uncertain water depths. The annual probability averaged over all possible models’ parameters is used to develop hazard maps that account for epistemic uncertainties. Results are compared to traditional hazard maps, showing that not including epistemic uncertainties can underestimate the hazard and lead to non‐conservative designs, and that this trend increases with return period. Results also show that the influence of the uncertainty in the future occurrence of discharge events is predominant over the inundation simulator uncertainties for the case study.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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The Cost of Imperfect Knowledge: How Epistemic Uncertainties Influence Flood Hazard Assessments

Balbi,

Lallemant

2023

Water Resources Research

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Advanced floodplain mapping: HEC-RAS and ArcGIS pro application on Swat River

Ullah,

Qureshi,

Rauf

et al. 2024

J. Umm Al-Qura Univ. Eng.Archit.

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Floods stand out as one of the most devastating environmental threats worldwide resulting in the tragic loss of human lives and significant damage to our essential infrastructure. This study focuses on creating floodplain maps for the two important reaches of Swat River in the Khyber Pakhtunkhwa Province of Pakistan, namely, Kalam–Khwazakhela and Khwazakhela–Chakdara reaches. The Advanced Land Observing Satellite Phased Array Type L-band Synthetic Aperture Radar (ALOS PALSAR) 12.5 m Digital Elevation Model (DEM) data has been used for this purpose. Furthermore, the sensitivity of the flood model was assessed for the Flood 2022 event, considering simulated flood depth, extent, and velocity in relation to various terrains derived from the 12.5-m ALOS PALSAR data. To estimate extreme flows for different return periods (2, 5, 10, 25, 50, and 100 years), the Log Normal (LN), Log Pearson III (LP3), and Generalized Extreme Value (GEV) distributions were employed for the frequency analysis. The GEV distribution turned out to be the best fit for modeling the Swat River for both the Chakdara and Khwazakhela gauge stations. To predict flood levels for the peak floods identified through frequency analysis and for the specific return periods the Hydrologic Engineering Center's River Analysis System (HEC-RAS) 2D simulations were performed. Subsequently the outcomes of this model were used to create floodplain maps using Geographic Information System Professional (ArcGIS Pro) software customized for various return periods. The analysis revealed a linear increase in flood inundation area with longer return periods. The floodplain maps developed hold significant importance for the governing authorities of the Swat region. These maps serve as essential tools for implementing proactive measures against potential infrastructure damage, thereby protecting against economic losses and enhancing public safety. This research effectively combines hydrological modeling and geospatial technology offering practical solutions for managing flood risks. It serves as a valuable guide for making well-informed decisions and promoting sustainable development in flood-prone areas.

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Climate change impact on flood inundation along the downstream reach of the Humber River basin

Sarchani,

Tsanis

2024

Journal of Hydrology: Regional Studies

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Understanding Uncertainty in Probabilistic Floodplain Mapping in the Time of Climate Change

Cited by 9 publications

References 80 publications

The Cost of Imperfect Knowledge: How Epistemic Uncertainties Influence Flood Hazard Assessments

The Cost of Imperfect Knowledge: How Epistemic Uncertainties Influence Flood Hazard Assessments

Advanced floodplain mapping: HEC-RAS and ArcGIS pro application on Swat River

Climate change impact on flood inundation along the downstream reach of the Humber River basin

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