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Water Resources Management
Published in: Water Resources Management 13/2018

09-08-2018

Nonstationary Flood Frequency Analysis for Annual Flood Peak and Volume Series in Both Univariate and Bivariate Domain

Authors: Jianzhu Li, Yuming Lei, Senming Tan, Colin D. Bell, Bernard A. Engel, Yixuan Wang

Published in: Water Resources Management | Issue 13/2018

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Abstract

Flood frequency analysis for practical application is traditionally based on the assumption of stationarity, but this assumption has been open to doubt in recent years. A number of studies have focused on the nonstationary flood frequency analysis, and the associated causes of nonstationarity. In this study, the annual maximum flood peak and flood volume of Wangkuai reservoir watershed were used, and several univariate and bivariate models were established to investigate the nonstationary flood frequency, with the distribution parameters changing over the climate indices (NPO, Niño3) and the check dam indices (CDIp, CDIv). In the univariate models, the Weibull distribution performed best and exhibited an undulate behavior for both flood peak and volume, which tended to describe the nonstationarity reasonably well. The bivariate models were constructed using copulas, of which the optimal Weibull distribution in the univariate flood frequency analysis was considered as marginal distributions within the joint distribution. The results showed that the Gumbel-Hougaard copula offered the best joint distribution, and most of the probability isolines crossed each other, which demonstrated the possibility that the occurrence of combinations of the flood peak and volume may be the same under multiple effects of phase changes in the climate patterns and certain human activities (i.e. soil and water conservation). The most likely events were elaborated in diagrams, and the associated combinations of the flood peak and volume were smaller than that estimated by the fixed parameters (i.e. stationary condition) during most of the study period, while it was the opposite in 1956, 1959 and 1963. The results highlight the necessity of nonstationary flood frequency analysis under various conditions in both univariate and multivariate domains.
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Literature
Abdollahi K, Guzman P, Huysmans M et al (2016) Rainfall-runoff modelling using a spatially distributed electrical circuit analogue. Nat Hazards 2:1279–1300CrossRef
Akaike H (1974) A new look at the statistical model identification. IEEE Trans Autom Control 19:716–723CrossRef
Bender J, Wahl T, Jensen J (2014) Multivariate design in the presence of non-stationarity. J Hydrol 514:123–130CrossRef
Cancelliere A (2017) Non stationary analysis of extreme events. Water Resour Manag 31:3097–3110CrossRef
Cooley D (2013) Return periods and return levels under climate change: extremes in a changing climate. Springer, Netherlands, pp 97–114CrossRef
Filliben JJ (1975) The probability plot correlation coefficient test for normality. Technometrics 17:111–117CrossRef
Gräler B, van den Berg MJ, Vandenberghe S et al (2013) Multivariate return periods in hydrology: a critical and practical review focusing on synthetic design hydrograph estimation. Hydrol Earth Syst Sci 17:1281–1296CrossRef
Gül GO, Aşıkoğlu ÖL, Gül A et al (2014) Nonstationarity in flood time series. J Hydrol Eng 19:1349–1360CrossRef
Hejazi MI, Markus M (2009) Impacts of urbanization and climate variability on floods in northeastern Illinois. J Hydrol Eng 14:606–616CrossRef
Jiang C, Xiong LH, Xu CY et al (2015) Bivariate frequency analysis of nonstationary low-flow series based on the time-varying copula. Hydrol Process 29:1521–1534CrossRef
Karmakar S, Simonovic SP (2009) Bivariate flood frequency analysis. Part 2: a copula-based approach with mixed marginal distributions. J Flood Risk Manag 2:32–44CrossRef
Li JZ, Liu XY, Chen FL (2015) Evaluation of nonstationarity in annual maximum flood series and the associations with large-scale climate patterns and human activities. Water Resour Manag 29:1653–1668CrossRef
Li JZ, Tan SM (2015) Nonstationary flood frequency analysis for annual flood peak series, adopting climate indices and check dam index as covariates. Water Resour Manag 29:5533–5550CrossRef
López J, Francés F (2013) Non-stationary flood frequency analysis in continental Spanish rivers, using climate and reservoir indices as external covariates. Hydrol Earth Syst Sci 17:3189–3203CrossRef
Merz B, Vorogushyn S, Uhlemann S et al (2012) HESS opinions more efforts and scientific rigour are needed to attribute trends in flood time series. Hydrol Earth Syst Sci 16(5):1379–1387CrossRef
Milly PCD, Betancourt J, Falkenmark M et al (2008) Stationarity is dead: whither water management? Science 319:573–574CrossRef
Montanari A, Koutsoyiannis D (2014) Modeling and mitigating natural hazards: stationarity is immortal. Water Resour Res 50:9748–9756CrossRef
Nelsen RB (2006) An introduction to copulas. Springer
Olsen JR, Lambert JH, Haimes YY (1998) Risk of extreme events under nonstationary conditions. Risk Anal 18:497–510CrossRef
Pramanik N, Panda RK, Sen D (2010) Development of design flood hydrographs using probability density functions. Hydrol Process 24:415–428
Prosdocimi I, Kjeldsen TR, Miller JD (2015) Detection and attribution of urbanization effect on flood extremes using nonstationary flood-frequency models. Water Resour Res 51:4244–4262CrossRef
Ouarda TBMJ, El-Adlouni S (2011) Bayesian nonstationary frequency analysis of hydrological variables. J Am Water Resour Assoc 47:497–506CrossRef
Rigby RA, Stasinopoulos DM (2005) Generalized additive models for location, scale and shape. J Royal Stat Soc: Ser C (Appl Stat). 54:507–554CrossRef
Silva AT, Portela MM, Naghettini M (2012) Nonstationarities in the occurrence rates of flood events in Portuguese watersheds. Hydrol Earth Syst Sci 16:241–254CrossRef
Salas J, Obeysekera J (2014) Revisiting the concepts of return period and risk for nonstationary hydrologic extreme events. J Hydrol Eng 19:554–568CrossRef
Serinaldi F (2015) Dismissing return periods. Stoch Env Res Risk A 29:1179–1189CrossRef
Shiau JT, Wang HY, Tsai CT (2007) Bivariate frequency analysis of floods using copulas. JAWRA J Am Water Resour Assoc 42:1549–1564CrossRef
Sklar A (1959) Fonctions de répartition à n dimensions et leurs marges. Publications de Institut de Statistique Université de Paris 8:229–231
Sraj M, Bezak N, Brilly M (2015) Bivariate flood frequency analysis using the copula function: a case study of the Litija station on the Sava river. Hydrol Process 29:225–238CrossRef
Stasinopoulos DM, Rigby RA, Akantziliotou C (2004) Instructions on how to use the GAMLSS package in R. Technical report 02/04. STORM Research Centre, London Metropolitan University, London
Stasinopoulos DM, Rigby RA (2007) Generalized additive models for location scale and shape (GAMLSS) in R. J Stat Softw 23:1–46CrossRef
Strupczewski WG, Singh VP, Mitosek HT (2001) Non-stationary approach to at-site flood frequency modelling. III. Flood analysis of polish rivers. J Hydrol 248:152–167CrossRef
Strupczewski WG, Kochanek K, Feluch W et al (2009) On seasonal approach to nonstationary flood frequency analysis. Phys Chem Earth 34:612–618CrossRef
Tramblay Y, Neppel L, Carreau J et al (2013) Non-stationary frequency analysis of heavy rainfall events in southern France. Hydrol Sci J 58:280–294CrossRef
Tsakiris G, Kordalis N, Tsakiris V (2015) Flood double frequency analysis: 2D-Archimedean copulas vs bivariate probability distributions. Environ Process 2:705–716CrossRef
Um MJ, Heo JH, Markus M et al. (2017) Performance evaluation of four statistical tests for trend and non-stationarity and assessment of observed and projected annual maximum precipitation series in major United States cities. Water resources management (accepted)
Vasiliades L, Galiatsatou P, Loukas A (2015) Nonstationary frequency analysis of annual maximum rainfall using climate covariates. Water Resour Manag 29:339–358CrossRef
Villarini G, Smith JA, Napolitano F (2010) Nonstationary modeling of a long record of rainfall and temperature over Rome. Adv Water Resour 33:1256–1267CrossRef
Vogel RM, Yaindl C, Walter M (2011) Nonstationary: flood magnification and recurrence reduction factors in the unite states. J Am Water Resour Assoc 47:464–474CrossRef
Wilson D, Hisdal H, Lawrence D (2010) Has streamflow changed in the Nordic countries?– recent trends and comparisons to hydrological projections. J Hydrol 394:334–346CrossRef
Zhang L, Singh VP (2006) Bivariate flood frequency analysis using the copula method. J Hydrol Eng 11:150–164CrossRef
Zhang L, Singh VP (2007) Trivariate flood frequency analysis using the Gumbel-Hougaard copula. J Hydrol Eng 12:431–439CrossRef
Metadata
Title
Nonstationary Flood Frequency Analysis for Annual Flood Peak and Volume Series in Both Univariate and Bivariate Domain
Authors
Jianzhu Li
Yuming Lei
Senming Tan
Colin D. Bell
Bernard A. Engel
Yixuan Wang
Publication date
09-08-2018
Publisher
Springer Netherlands
Published in
Water Resources Management / Issue 13/2018
Print ISSN: 0920-4741
Electronic ISSN: 1573-1650
DOI
https://doi.org/10.1007/s11269-018-2041-2

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