A regional comparative analysis of empirical and theoretical flood peak-volume relationships

Szolgay, Ján; Gaál, Ladislav; Bacigál, Tomáš; Kohnová, Silvia; Hlavčová, Kamila; Výleta, Roman; Parajka, J.; Blöschl, Günter

doi:10.1515/johh-2016-0042

Cited by 31 publications

(25 citation statements)

References 47 publications

(75 reference statements)

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“…Gaál et al (2012Gaál et al ( , 2015 and Szolgay et al (2016) found similar results when they 20 analyzed durations of flood events across Austria. They found that the flood event duration consistently increases with increasing snow-to-rainfall ratio of the process leading to the event despite the diversity of the non-climate catchment characteristics that have impact on the flood generation process that affect the flood event duration.…”

Section: Discussionmentioning

confidence: 65%

Flood type classification and assessment of their past changes across Europe

Hundecha

Parajka

Viglione

2017

Preprint

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Abstract. This study was carried out to establish the characteristics of observed flood events across Europe in the past in terms of their spatial extent and the processes leading up to the events. Daily discharge data from more than 745 stations of 10 the Global Runoff Data Centre were used to identify peak flows at each station for the period 1961-2010. The identified events at the different stations were further analysed to determine whether they form the same flood event, thereby delineating the spatial extent of the flood events. A pan-European hydrological model was employed to estimate a set of catchment hydrological and hydro-meteorological state variables that are relevant in the flood generation process for each of the identified spatially delineated flood events. A subsequent clustering of the events based on the simulated state variables 15 was used to identify the flood generation mechanism of each flood event. Four general flood generation mechanisms were identified: long-rain flood, short-rain flood, snowmelt flood, and rain-on-snow flood. A trend analysis was performed to investigate how the frequency of each of the flood types has changed in time over the investigation period. In order to investigate whether there is a regional and seasonal pattern in the dominant flood generating mechanisms, this analysis was performed separately for winter and summer seasons and five different regions of Europe: Northern, Western, Eastern, 20Southern Europe, and the Alps. Continentally, the total number of flood events didn't show a significant change. However, the frequency of winter long rain events increased significantly while that of summer rain-on-snow events decreased significantly over the investigation period. Regional differences were detected in the dominant flood generating mechanism and the corresponding trends. In Western Europe, the frequency of both winter and summer rainfall events increased significantly. In Northern and Eastern Europe, the frequency of summer rain-on-snow events decreased significantly. In 25 addition, winter short rainfall events increased significantly in Eastern Europe. In the Alps, the frequency of summer short rain events increased significantly.Hydrol. Earth Syst. Sci. Discuss., https://doi

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Section: Discussionmentioning

confidence: 65%

Flood type classification and assessment of their past changes across Europe

Hundecha

Parajka

Viglione

2017

Preprint

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“…where F Q f ;Q s q f ; q s is the joint CDF of fast flow and slow flow; F Q f q f is the CDF of fast flow; F Q s q s ð Þ is the CDF of slow flow; and C is a copula function which quantifies the joint CDF of fast flow and slow flow as a function of F Q f q f and F Q s q s ð Þ. Copulas have been applied for characterizing complex hydrological events such as floods through a small number of dependent variables such as flood peak, volume, and duration (Favre et al, 2004;Grimaldi & Serinaldi, 2006;Salvadori & De Michele, 2004;Szolgay et al, 2016;Zhang & Singh, 2007). Kao and Govindaraju (2008) applied a trivariate copula to characterize the temporal distribution of extreme rainfall.…”

Section: Quantifying the Dependence Of Fast And Slow Flows Using Copulamentioning

confidence: 99%

A New Framework for Exploring Process Controls of Flow Duration Curves

Ghotbi

Wang

Singh

et al. 2020

Water Resources Research

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The flow duration curve (FDC) is effectively the cumulative distribution function of streamflow. For a long time, hydrologists have sought deeper understanding of the process controls on the shape of FDC, which has been a challenge due to contrasting processes controlling the fast flow and slow flow components of streamflow and their interactions. In this paper, we outline a new framework for exploring the process controls of the FDC, which involves studying fast and slow flow components of FDC separately and combining them statistically, explicitly accounting for their dependence. We illustrate the potential of the framework by constructing empirical fast flow duration (FFDC) and slow flow duration (SFDC) curves from the flow components obtained by traditional baseflow separation. Streamflow time series data from 245 MOPEX catchments across the continental United States are used. The dependence of FFDC and SFDC components is captured by the Gumbel copula, the strength of which varies regionally. In catchments where FFDC and SFDC are independent, FDC can be approximated by a simple convolution of FFDC and SFDC. The proposed conceptual framework opens the way for future modeling studies to explore process controls of fast and slow components of streamflow separately, their dependence, and their relative contributions to the shape of the FDC.

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“…Volpi and Fiori [2] used Gumbel-Hougaard copulas to model dependency between peak and volume in flood analysis; Gräler et al [1] used synthetic dataset to show difference in performance of 2D and 3D copulas for various combinations of hydrologic variables; Xu et al [5] compared four Archimedean family copulas for derivation of a design flood hydrograph; Bender et al [14] used Gumbel copula for bivariate analysis of concurrent flows at a river confluence, and Bender et al [15] continued to investigate bivariate analysis of discharges on confluences, investigating sites where floods do not occur simultaneously. Szolgay et al [16] evaluated applicability of different copula types to a peakvolume flood relationship over a large region in Austria and its sub-catchments, and also studied the influence of the data series length on bivariate copula performance. Sraj et al [17] compared three copula families for bivariate flood frequency analysis in the Sava River basin in Slovenia, and the results obtained by Ozga-Zielinski et al [18] showed that the Gumbel-Hougaard copula yields better results compared to Gaussian copula for snowmelt floods.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Joint probability analysis of flood hazard at river confluences using bivariate copulas

Gilja¹,

Ocvirk²,

Kuspilić³

2018

JCE

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Joint probability analysis of flood hazard at river confluences using bivariate copulas Estimation of flood hazard associated with return period of a hydrologic event is the basis for design of flood protection structures. More frequent occurrence of flood events in recent history has imposed the need to reconsider traditional hydrological approaches to estimation of high flow events. This paper focuses on estimation of peak flood discharge at two confluences of the Sava River. The results show that the peak discharge trend estimated using bivariate copulas is comparable to the values measured during an extreme flood event in 2014.

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A regional comparative analysis of empirical and theoretical flood peak-volume relationships

Cited by 31 publications

References 47 publications

Flood type classification and assessment of their past changes across Europe

Flood type classification and assessment of their past changes across Europe

A New Framework for Exploring Process Controls of Flow Duration Curves

Joint probability analysis of flood hazard at river confluences using bivariate copulas

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