Hydrological simulation of flood transformations in the upper Danube River: Case study of large flood events

Angelini, H., 1955. Danube flood in July 1954, Bratislava. Hydrological Study. HMI Department of Hydrology, Bratislava, Slovak Republic, 34 p. (In Slovak.)Search in Google Scholar

Bardossy, A., Molnar, Z., 2004. Statistical and geostatistical investigations into the effects of the Gabcikovo hydropower plant on the groundwater resources of northwest Hungary. Hydrol. Sci. J., 49, 4, 611–623.10.1623/hysj.49.4.611.54423Search in Google Scholar

Blaškovičová, L., Danáčová, Z., Lovasová, L., Simor, V., Škoda, P., 2013. Evolution of selected hydrological characteristics of the Danube at Bratislava. Hydrological Final Report. Slovak Hydrometeorological Institute, Bratislava, pp. 1–15. (In Slovak.)Search in Google Scholar

Blöschl, G., Nester, T., Komma, J., Parajka, J., Perdigão, R.A.P., 2013. The June 2013 flood in the Upper Danube basin, and comparisons with the 2002, 1954 and 1899 floods. Hydrol. Earth Syst. Sci., 17, 7, 9533–9573.10.5194/hessd-10-9533-2013Search in Google Scholar

Brázdil, R., Kundzewicz, Z.W., 2006. Historical hydrology – Editorial. Hydrol. Sci. J., 51, 5, 733–738.10.1623/hysj.51.5.733Search in Google Scholar

Corbus, C., 2002. Contributions to approaching the floods propagation with the help of the theory of the systems. In: Proc. XXI Conference of the Danube Countries on Hydrological Forecasting (Bucharest, Romania). National Institute of Meteorology and Hydrology, Bucharest, ISBN 973-0-02759-5.Search in Google Scholar

Čížová, M., 1992. Influence of hydrological forecast by anthropogenic activity. In: Proc. XVI Conference of the Danube Countries on Hydrological forecasting, Kelheim, Germany, pp. 301–305.Search in Google Scholar

Danáčová, M., Szolgay, J., Výleta R., 2015. Estimation of the relationship between the travel time of flood peaks and peak discharge on the Poprad River by Multilinear flood routing. International Journal of New Technology and Research (IJNTR), 1, 6, 2015, 35–39. ISSN: 2454-4116Search in Google Scholar

Goodrich, R.D., 1931. Rapid calculation of reservoir discharge. Civ. Eng., 1, 417–418.Search in Google Scholar

Horváthová, B., 2003. Flood is not only the High Water. VEDA, Bratislava, 232 p. (In Slovak.)Search in Google Scholar

Kalinin, G.P., Milyukov, P.I., 1957. On the computation of unsteady flow in open channels. Meteorol. Gidrol. Z., 10, 10–18.Search in Google Scholar

Kim, D.H., Georgakakos, A.P., 2014. Hydrologic routing using nonlinear cascaded reservoirs. Water Resour. Research., 50, 8, 7000–7019.10.1002/2014WR015662Search in Google Scholar

Kiss, A., 2011. Floods and long-term water-level changes in medieval Hungary. Doctoral dissertation. Central European University Budapest, Hungary, 323 p.Search in Google Scholar

Kjeldsen, T.R., Macdonald, N., Lang, M., Mediero, L., Albuquerque, T., Bogdanowicz, E., Brázdil, R., Castellarin, A., David, V., Fleig, A., Gul, G.O., Kriauciuniene, J., Kohnova, S., Merz, B., Nicholson, O., Roald, L.A., Salinas, J.L., Sarauskiene, D., Sraj, M., Strupczewski, W., Szolgay, J., Toumazis, A., Vanneuville, W., Veijalainen, N., Wilson, D., 2014. Documentary evidence of past floods in Europe and their utility in flood frequency estimation. J. Hydrol., 517, 963–973. ISSN 0022-1694.10.1016/j.jhydrol.2014.06.038Search in Google Scholar

Kresser, W., 1957. The Flooding of the Danube. Springer Verlag, Vienna, Austria. (In German.)Search in Google Scholar

Laurenson, M., 1964. A catchment storage model for runoff routing. J. Hydrol., 2, pp. 141–163.10.1016/0022-1694(64)90025-3Search in Google Scholar

Linsley, R.K., Kohler, M.A., Paulhus, J.L.H., 1949. Applied Hydrology. McGraw Hill, New York, pp. 502–530.Search in Google Scholar

Malone, T.A., Cordery, I., 1989. An assessment of network models in flood forecasting. New directions of surface water modelling. In: Kavvas, M.L. (Ed.): Proceedings of Baltimore Symposium. IAHS 181. IAHS Press, Wallingford, pp. 115–124.Search in Google Scholar

McCarthy, G.T., 1938. The unit hydrograph and flood routing. In: Proc. Conference of the North Atlantic Division of US Corporations of Engineers, New London, Conn.Search in Google Scholar

Melo, M., Pišút, P., Melová, K., Viglaš, P., 2014. Historical flood marks from the 1775 Danube flood in Bratislava. Acta Hydrologica Slovaca, 15, 2, 308–319. (In Slovak.)Search in Google Scholar

Mikhailova, M., Morozov, V., Cheroy N., 2012. Extreme hydrological events in the Danube River basin over the last decades. Water Resour., 39, 2, 161–179.10.1134/S0097807812010095Search in Google Scholar

Mitková, V., 2005. Transformation of the flood waves of the Danube River in Kienstock – Sturovo reach. In: CD ROM Proc. Conf. Hydrological days 2005 – Hydrology for integrated management of the water resources and Conference of young specialists in hydrology, climatology and water managers. SHMI, STU, Bratislava, pp. 784–795, ISBN 80-88907-53-5.Search in Google Scholar

Mitková, V., Pekárová, P., 2003. The water levels forecast of the August 2002 flood of the Danube River at Bratislava station. Acta Hydrologica Slovaca, 4, 1, 176–182. (In Slovak.)Search in Google Scholar

Mitková, V., Kubeš, R., Szolgay, J., Pekárová, P., 2004. Simulation of 1899 and 1954 Danube flood waves transformation in the river reach Kienstock – Bratislava in the present hydraulic conditions. Acta Hydrologica Slovaca, 5, 1, 52–62. (In Slovak.)Search in Google Scholar

Mitková, V., Pekárová, P., Miklánek, P., Pekár, J., 2005. Analysis of flood propagation changes in the Kienstock – Bratislava reach of the Danube River. Hydrol. Sci. J., 50, 4, 655–668.10.1623/hysj.2005.50.4.655Search in Google Scholar

Nash, J.E., 1957. The form of the instantaneous unit hydrograph. In: Proc. IAHS General Assembly, Toronto, Canada, pp. 3–14.Search in Google Scholar

Nash, J.E., 1960. A unit hydrograph study with particular reference to British catchments, Proc. Inst. Civ. Eng., 17, 249–282.10.1680/iicep.1960.11649Search in Google Scholar

Opatovská, G., 2002. Influence of sedimentation on water level changes of Danube in Bratislava. Vodohosp. Sprav., 4, 11–12. (In Slovak.)Search in Google Scholar

Pekárová, P., Pekár, J., Miklánek, P., 2001. River model of nonlinear cascade NLN-Danube of Danube River between Ybbs and Nagymaros in EXCEL 97. Acta Hydrologica Slovaca, 2, 2, 241–246.Search in Google Scholar

Pekárová, P., Szolgay, J., Mitková, V., Kubeš, R., 2004. Calibration of two hydrologic routing models of the Danube flood waves transformation between Kienstock – Bratislava river reach. Acta Hydrologica Slovaca, 5, 1, 24–33.Search in Google Scholar

Pekárová, P., Miklánek, P., Melo, M., Halmová, D., Pekár, J., Bačová Mitková, V., 2014. Flood Marks along the Danube River between Passau and Bratislava. Veda, Bratislava, 102 p. ISBN 978-80-224-1408-1.Search in Google Scholar

Perumal, M., Price, R.K., 2013. A fully mass conservative variable parameter McCarthy–Muskingum method: theory and verification. J. Hydrol., 502, 89–102. doi: 10.1016/j.jhydrol.2013.08.023.10.1016/j.jhydrol.2013.08.023Search in Google Scholar

Price, R.K., 1973. Flood routing methods for British rivers. Proc. Inst. Civ. Eng., 15, 913–930.10.1680/iicep.1973.4147Search in Google Scholar

Price, R.K., 2009. Volume conservative non-linear flood routing. J. Hydraul. Eng. ASCE, 135, 10, 838–845.10.1061/(ASCE)HY.1943-7900.0000088Search in Google Scholar

Sahoo, B., 2013. Field application of the multilinear Muskingum discharge routing method. Water Resour. Manag., 27, 1193–1205. doi: 10.1007/s11269-012-0228-5.10.1007/s11269-012-0228-5Search in Google Scholar

Svoboda, A., 1969. Changes in flood regime along the river channel. Partial Report IH SAS, Bratislava. (In Slovak.)Search in Google Scholar

Svoboda, A., 1970. Some practical aspects use the mathematical models in hydrology. J. Hydrol. Hydromech., 18, 3, 225–238.Search in Google Scholar

Svoboda, A., Hajtášová, K., 1996. Comparison of short-term forecasting methods on the Danube used after completion of the Gabcikovo structure. In: Proc. XVIII Conf. of the Danube Countries. Technical University, Graz, Austria, pp. B133–B139.Search in Google Scholar

Svoboda, A., Pekárová, P., Miklánek, P., 2000. Flood Hydrology of Danube between Devín and Nagymaros. SVH – IH SAS, Bratislava, 96 p.Search in Google Scholar

Szilagyi, J., Pinter, N., Venczel, R., 2008. Application of a routing model for detecting channel flow changes with minimal data. J. Hydrol. Eng., 10.1061/(ASCE)1084-0699(2008)13:6(521), 521–526.Search in Google Scholar

Szolgay, J., 2003. Multilinear discrete cascade model for river flow routing and real time forecasting in river reaches with variable wave speed. In: Montanari et al. (Eds.): Proceedings of the ESF LESC Exploratory Workshop on Hydrological Risk: recent advances in peak river flow modeling, prediction and real-time forecasting. Assessment of the impacts of land use and climate changes. University of Bologna, Bologna, Italy, 14 p.Search in Google Scholar

Tang, X., Knight, D.W., Samuels, P.G., 2001. Wave speed discharge relationship from cross-section survey. Water and Maritime Eng., 148, 2, 81–96.10.1680/wame.2001.148.2.81Search in Google Scholar

Tarpanelli, A, Barbetta, S., Brocca, L., Moramarco, T., 2013. River discharge estimation by using altimetry data and simplified flood routing modeling. Remote Sensing, 5, 9, 4145–4162. doi: 10.3390/rs5094145.10.3390/rs5094145Search in Google Scholar

Todini, E., 2007. A mass conservative and water storage consistent variable parameter Muskingum-Cunge approach. Hydrol. Earth Syst. Sci., 11, 1645–1659.10.5194/hess-11-1645-2007Search in Google Scholar

Wong, T.H.F., Laurenson, E.M., 1984. A model of flood wave speed - discharge characteristics of rivers. Water Resources Res., 20, 1883–1890.10.1029/WR020i012p01883Search in Google Scholar