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Articles
  • OpenAccess
  • Flood Risk for Embanked Rivers  [HOAC 2014]
  • DOI: 10.4236/gep.2014.23018   PP.135 - 143
  • Author(s)
  • Ewa Bogdanowicz, Witold G. Strupczewski, Krzysztof Kochanek, Iwona Markiewicz
  • ABSTRACT

  • Flood frequency analysis (FFA) concentrates on peak flows of flood hydrographs. However, floods that last years devastated large parts of Poland lead us to revision of the views on the assessment of flood risk in Poland. It turned out that it is the prolonged exposure to high water on levees that causes floods, not only the water overflowing the levee crest. This is because, the levees are weakened by water and their disruption occurs when it seems that the danger is over, i.e. after passing culmination. Two main causes of inundation of embanked rivers, namely over-crest flow and wash out of the levees, are combined to assess the total risk of inundation. Therefore the risk of inundation is the total of risk of exceeding embankment crest by flood peak and risk of washout of levees. Hence, while modeling the flood events in addition to the maximum flow one should consider also the duration of high water in a river channel, Analysis of the frequency of annual peak flows based on annual maxima and peaks over threshold is the subject of countless publications. Therefore we will here mainly modeling the duration of high water levels. In the paper the two-component model of flood hydrograph shape i.e. “duration of flooding-discharge- probability of nonexceedance” (DqF), with the methodology of its parameters estimation for stationary case was developed as a completion to the classical FFA with possible extension to non stationary flood regime. The model combined with the technical evaluation of probability of levees breach due to the d-days duration of flow above alarm stage gives the annual probability of inundation caused by the embankment breaking. The results of theoretical research were supplemented by a practical example of the model application to the series for daily flow in the Vistula River in Szczucin. Regardless promising results, this method is still in its infancy despite its great cognitive potential and practical importance. Therefore, we would like to point to the usefulness and necessity of the DqF models to the one-dimensional analysis of the peak flood hydrographs and to flood risk analysis. This approach constitutes a new direction in FFA for embanked rivers.

  • KEYWORDS
  • Flood Frequency Analysis, Levee Break, Flood Duration, Maximum Likelihood, Nonstationarity
  • References
  • [1]
    Bogdanowicz, E., Strupczewski, W. G., & Kochanek, K. (2011). Persistence as a Factor of Flood Hazard for Embanked Rivers. EGU Leonardo Conference “Floods in 3D”, Bratislava, 23-25 November 2011, Abstract in Proceedings.
    [2]
    Gilliom, R. J., & Helsel, D. R. (1986). Estimation of Distributed Parameters for Censored Trace Level Water Quality Data-1. Estimation techniques. Water Resources Research, 22, 1201-1206.
    [3]
    Gupta, R. D., & Kundu, D. (2000). Generalized Exponential Distribution: Different Method of Estimations. Journal of Statistical Computation and Simulation, 1-22.
    [4]
    Haas, C. N., & Scheff, P. A., (1990). Estimation of Averages in Truncated Samples. Environmental Science & Technology, 24, 912-919.
    http://dx.doi.org/10.1021/es00076a021
    [5]
    Harlow, D. G. (1989). Effect of Proof-Testing on the Weibull Distribution. Journal of Materials Science, 24, 1467-1473.
    http://dx.doi.org/10.1007/BF02397087
    [6]
    Helsel, D. R. (1990). Less Than Obvious: Statistical Treatment of Data Below Detection Limit. Environmental Science & Technology, 24, 1767-1774.
    [7]
    Interagency Advisory Committee on Water Data (1982). Guidelines for Determining Flood Flow Frequency. Bulletin 17B, U.S. Department of the Interior, Geological Survey, Office of Water Data, Reston, Va.
    [8]
    Rao, A. R., & Hamed, K. H. (2000). Flood Frequency Analysis. CRC Press.
    [9]
    Strupczewski, W. G., Singh, V. P., & Weglarczyk, S. (2002). Physically Based Model of Discontinuous Distribution for Hydrological Samples with Zero Values. In S. Al-Rashed, & A. A. Sherif (Eds.), Proceedings of the Int. Conf. On WaRMAR, Kuwait. Surface Water Hydrology (pp. 523-537). Lisse: Balkema Publishers, Swets & Zeitlinger.
    [10]
    Strupczewski, W. G., Weglarczyk, S., & Singh, V. P. (2003). Impulse Response of the Kinematic Diffussion Model as a Probability Distribution of Hydrologic Samples with Zero Values. Journal of Hydrology, 270, 328-351.
    http://dx.doi.org/10.1016/S0022-1694(02)00309-8
    [11]
    Strupczewski, W. G., Kochanek, K., Markiewicz, I., Bogdanowicz, E., Weglarczyk, S., & Singh V. P. (2011). On the Tails of Distributions of Annual Peak Flow. Hydrology Research, 42, 171-192.
    http://dx.doi.org/10.2166/nh.2011.062
    [12]
    Wang, S. X., & Singh, V. P. (1995). Frequency Estimation for Hydrological Samples with Zero Values. Journal of Water Resources Planning and Management, ASCE, 121, 98-108.
    http://dx.doi.org/10.1061/(ASCE)0733-9496(1995)121:1(98)
    [13]
    Woo, M. K. & Wu, K. (1989). Fitting Annual Floods with Zero Flows. Canadian Water Resources Journal, 14, 10-16.
    http://dx.doi.org/10.4296/cwrj1402010
    [14]
    Weglarczyk, S., Strupczewski, W. G., & Singh, V. P. (2005). Three-Parameter Discontinuous Distributions for Hydrological Samples with Zero Values. Hydrologic Processes, 19, 2899-2914.

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