[ARCEMENT, G. J. (1989): Guide for Selecting Manning's Roughness Coefficients for Natural Channels and Flood Plains. United States Geological Survey: Water-Supply Paper 2339.]Search in Google Scholar
[BAKY, M. A. A., ISLAM, M., PAUL, S. (2019): Flood Hazard, Vulnerability and Risk Assessment for Different Land Use Classes Using a Flow Model. Earth Systems and Environment, 4(1): 225–244.10.1007/s41748-019-00141-w]Search in Google Scholar
[BATES, P. D., HORRITT, M., HERVOUET, J. M. (1998): Investigating two-dimensional, finite element predictions of floodplain inundation using fractal generated topography. Hydrological Processes, 12(8): 1257–1277.10.1002/(SICI)1099-1085(19980630)12:8<1257::AID-HYP672>3.0.CO;2-P]Search in Google Scholar
[BAUGH, C. A., BATES, P. D., SCHUMANN, G., TRIGG, M. A. (2013): SRTM vegetation removal and hydrodynamic modelling accuracy. Water Resources Research, 49(9): 5276–5289.10.1002/wrcr.20412]Search in Google Scholar
[BERKHAHN, S., FUCHS, L., NEUWEILER, I. (2019): An ensemble neural network model for real-time prediction of urban floods. Journal of Hydrology, 575: 743–754.10.1016/j.jhydrol.2019.05.066]Search in Google Scholar
[BEVEN, K. J. (2009): Environmental Modelling: An Uncertain Future?. Abingdon, Routledge.]Search in Google Scholar
[BLADÉ, E. et al. (2014): Iber: herramienta de simulación numérica del flujo en ríos. Revista Internacional de Métodos Numéricos para Cálculo y Diseńo en Ingeniería, 30(1): 1–10.10.1016/j.rimni.2012.07.004]Search in Google Scholar
[BLÖSCHL, G. et al. (2020): Current European flood-rich period exceptional compared with past 500 years. Nature, 583: 560–566.10.1038/s41586-020-2478-3]Search in Google Scholar
[BODOQUE, J. M., AMERIGO, M., DIEZ-HERRERO, A., GARCIA, J. A., CORTES, B., BALLESTEROS-CANOVAS, J. A., OLCINA, J. (2016): Improvement of resilience of urban areas by integrating social perception in flash-flood risk management. Journal of Hydrology, 541: 665–676.10.1016/j.jhydrol.2016.02.005]Search in Google Scholar
[BONACCI, O., LJUBENKOV, I., ROJE-BONACCI, T. (2006): Karst flash floods: an example from the Dinaric karst (Croatia). Natural Hazards and Earth System Sciences, 6(2): 195–203.10.5194/nhess-6-195-2006]Search in Google Scholar
[BRATH, A., MONTANARI, A., MORETTI, G. (2006): Assessing the effect on flood frequency of land use change via hydrological simulation (with uncertainty). Journal of Hydrology, 324(1–4): 141–153.10.1016/j.jhydrol.2005.10.001]Search in Google Scholar
[BRUNNER, G. W. (2016): HEC-RES River Analysis System - User's Manual Version 5.0. US Army Corps of Engineers. Institute for Water Resources, Hydrologic Engineering Center (HEC).]Search in Google Scholar
[BRYNDAL, T. (2015): Local flash floods in Central Europe: A case study of Poland. Norsk Geografisk Tidsskrift–Norwegian Journal of Geography, 69: 288–298.10.1080/00291951.2015.1072242]Search in Google Scholar
[CHEN, X., PARAJKA, J., SZÉLES, B., VALENT, P., VIGLIONE, A., BLÖSCHL, G. (2020): Impact of Climate and Geology on Event Runoff Characteristics at the Regional Scale. Water, 12(12): 3457.10.3390/w12123457]Search in Google Scholar
[CLUBB, F. J., MUDD, S. M., MILODOWSKI, D. T., VALTERS, D. A., SLATER, L. J., HURST, M. D., LIMAYE, A. B. (2017): Geomorphometric delineation of floodplains and terraces from objectively defined topographic thresholds. Earth Surface Dynamics, 5: 369–385.10.5194/esurf-5-369-2017]Search in Google Scholar
[ČUZK (n. d.): Digitální model reliéfu České republiky 5. generace (DMR 5G). URL: https://geoportal.cuzk.cz/(S(hg5uvv0eikuxv3c5pyise34q))/Default.aspx?mode=TextMeta&side=vyskopis&metadataID=CZ-CUZK-DMR5G-V&head_tab=sekce-02-gp&menu=302]Search in Google Scholar
[COSTABILE, P., MACCHIONE, F., NATALE, L., PETACCIA, G. (2015): Flood mapping using LIDAR DEM. Limitations of the 1-D modelling highlighted by the 2-D approach. Natural Hazards, 77(1): 181–204.10.1007/s11069-015-1606-0]Search in Google Scholar
[DIAKAKIS, M., DELIGIANNAKIS, G., ANDREADAKIS, E., KATSETSIADOU, K. N., SPYROU, N. I., GOGOU M. E. (2020): How different surrounding environments influence the characteristics of flash flood-mortality: The case of the 2017 extreme flood in Mandra, Greece. Journal of Flood Risk Management, 13(3): e12613.10.1111/jfr3.12613]Search in Google Scholar
[DIEHL, T. H. (1997): Potential Drift Accumulation at Bridges. Department of Transportation, Federal Highway Administration Research and Development, TurnerFairbank Highway Research Center, Virginia. Publication No. FHWA-RD-97-028.]Search in Google Scholar
[DINH, Q., BALICA, S., POPESCU, I., JONOSKI, A. (2012): Climate change impact on flood hazard, vulnerability and risk of the Long Xuyen Quadrangle in the Mekong Delta. International Journal of River Basin Management, 10(1): 103–120.10.1080/15715124.2012.663383]Search in Google Scholar
[DRBAL, K. et al. (2009): Vyhodnocení povodní v červnu a červenci 2009 na území České republiky. Metodika mapování povodňového rizika: Dílčí zpráva. Praha, VÚV TGM, Ministerstvo životního prostředí.]Search in Google Scholar
[DUB, O. (1957): Hydrológia, hydrografia, hydrometria. Slovenské vydavateľstvo technickej literatúry.]Search in Google Scholar
[ERNST, J., DEWALS, B. J., DETREMBLEUR, S., ARCHAMBEAU, P., ERPICUM, S., PIROTTON, M. (2010): Micro-scale flood risk analysis based on detailed 2D hydraulic modelling and high resolution geographic data. Natural Hazards, 55(2): 181–209.10.1007/s11069-010-9520-y]Search in Google Scholar
[EUROPEAN COMMISSION (2006): Proposal for and Directive of the European Parliament and of the Council on the assessment and management of floods. Brussels, Commission of the European Communities.]Search in Google Scholar
[EUROPEAN COMMISSION (2007): Directive 2007/60/EC of the European Parliament and of the Council of 23 October 2007 on the assessment and management of flood risks. European Parliament and Council. Official Journal of the European Union, L, 288: 27–34.]Search in Google Scholar
[FILIPOVA, V., HAMMOND, A., LEEDAL, D., LAMB, R. (2022): Prediction of flood quantiles at ungauged catchments for the contiguous USA using Artificial Neural Networks. Hydrology Research, 53(1): 107–123.10.2166/nh.2021.082]Search in Google Scholar
[FRAGOSO, M., TRIGO, R. M., PINTO, J. G., LOPES, S., LOPES, A., ULBRICH, S., MAGRO, C. (2012): The 20th February 2010 Madeira flash-floods: synoptic analysis and extreme rainfall assessment. Natural Hazards and Earth System Sciences, 12(3): 715–730.10.5194/nhess-12-715-2012]Search in Google Scholar
[GAÁL, L., SZOLGAY, J., KOHNOVÁ, S., PARAJKA, J., MERZ, R., VIGLIONE, A., BLÖSCHL, G. (2012): Flood timescales: Understanding the interplay of climate and catchment processes through comparative hydrology. Water Resources Research, 48(4): W04511.10.1029/2011WR011509]Search in Google Scholar
[GARROTE, J., ALVARENGA, F. M., DIEZ-HERRERO, A. (2016): Quantification of flash flood economic risk using ultra-detailed stage-damage functions and 2-D hydraulic models. Journal of Hydrology, 541: 611–625.10.1016/j.jhydrol.2016.02.006]Search in Google Scholar
[GAUME, E. et al. (2009): A compilation of data on European flash floods. Journal of Hydrology, 367(1–2): 70–78.10.1016/j.jhydrol.2008.12.028]Search in Google Scholar
[GRAY, D. M. (1964): Physiographic Characteristics and the Runoff Pattern. In: Proceedings of Hydrology Symposium No. 4 (pp. 147–164). National Research Council of Canada.]Search in Google Scholar
[GUTIÉRREZ, F., PARISE, M., DE WAELE, J., JOURDE, H. (2014): A review on natural and human-induced geohazards and impacts in karst. Earth-Science Reviews, 138: 61–88.10.1016/j.earscirev.2014.08.002]Search in Google Scholar
[GVOŽDÍKOVÁ, B., MÜLLER, M. (2017): Evaluation of extensive floods in western/Central Europe. Hydrology and Earth System Sciences, 21(7): 3715–3725.10.5194/hess-21-3715-2017]Search in Google Scholar
[HANZE: Historical Analysis of Natural Hazards in Europe (2017): T. U. Delft, Faculty of Civil Engineering and Geosciences, Department of Hydraulic Engineering.]Search in Google Scholar
[HAPUARACHCHI, H. A. P., WANG, Q. J., PAGANO, T. C. (2011): A review of advances in flash flood forecasting. Hydrological Processes, 25(18): 2771–2784.10.1002/hyp.8040]Search in Google Scholar
[HARDY, J., GOURLEY, J. J., KIRSTETTER, P. E., HONG, Y., KONG, F., FLAMIG, Z. L. (2016): A method for probabilistic flash flood forecasting. Journal of Hydrology, 541: 480–494.10.1016/j.jhydrol.2016.04.007]Search in Google Scholar
[HEWLETT, J. D., HIBBERT, A. R. (1967): Factors affecting the response of small watersheds to precipitation in humid areas. Forest hydrology, 1: 275–290.]Search in Google Scholar
[HUISMAN, J. A. et al. (2009): Assessing the impact of land use change on hydrology by ensemble modelling (LUCHEM) III: Scenario analysis. Advances in Water Resources, 32(2): 159–170.10.1016/j.advwatres.2008.06.009]Search in Google Scholar
[HYDRAULIC REFERENCE MANUAL IBER V. 1.0. (2014): Two-dimensional modelling of free surface shallow water flow.]Search in Google Scholar
[JARIHANI, A. A., CALLOW, J. N., MCVICAR, T. R., VAN NIEL, T. G., LARSEN, J. R. (2015): Satellite-derived Digital Elevation Model (DEM) selection, preparation and correction for hydrodynamic modelling in large, low-gradient and data-sparse catchments. Journal of Hydrology, (524): 489–506.10.1016/j.jhydrol.2015.02.049]Search in Google Scholar
[KANDILIOTI, G., MAKROPOULOS, C. (2011): Preliminary flood risk assessment: the case of Athens. Natural Hazards. 61(2): 441–468.10.1007/s11069-011-9930-5]Search in Google Scholar
[KREIBICH, H., BUBECK, P., VLIET, M. V., MOEL, H. D. (2015): A review of damage-reducing measures to manage fluvial flood risks in a changing climate. Mitigation and Adaptation Strategies for Global Change, 20(6): 967–989.10.1007/s11027-014-9629-5]Search in Google Scholar
[KREIBICH, H., PIROTH, K., SEIFERT, I., MAIWALD, H., KUNERT, U., SCHWARZ, J., MERZ, B., THIEKEN, A. H. (2009): Is flow velocity a significant parameter in flood damage modelling? Natural Hazards and Earth System Sciences, 9(5): 1679–1692.10.5194/nhess-9-1679-2009]Search in Google Scholar
[KRZHIZHANOVSKAYA, V. V. et al. (2011): Flood early warning system: design, implementation and computational modules. In: International Conference on Computational Science: Procedia Computer Science, 4: 106–115.10.1016/j.procs.2011.04.012]Search in Google Scholar
[KOURGIALAS, N. N., KARATZAS, G. P. (2011): Flood management and a GIS modelling method to assess flood-hazard areas—a case study. Hydrological Sciences Journal, 56(2): 212–225.10.1080/02626667.2011.555836]Search in Google Scholar
[KUKAL, Z. (2005): Geologická role řek v krajině. In: KENDER, J., POŠMOURNÝ, K., KUKAL, Z. [eds.]: Krajina v geologii – geologie v krajině (pp. 45–46). Praha, Ministerstvo životního prostředí ČR.]Search in Google Scholar
[KUNDZEWICZ, Z. W. et al. (2014): Flood risk and climate change: global and regional perspectives. Hydrological Sciences Journal, 59(1): 1–28.10.1080/02626667.2013.857411]Search in Google Scholar
[KUNDZEWICZ, Z. W., PIŃSKWAR, I., BRAKENRIDGE, G. R. (2018): Changes in river flood hazard in Europe: a review. Hydrology Research, 49(2): 294–302.10.2166/nh.2017.016]Search in Google Scholar
[LAUBER, U., KOTYLA, P., MORCHE, D., GOLDSCHEIDER, N. (2014): Hydrogeology of an Alpine rockfall aquifer system and its role in flood attenuation and maintaining baseflow. Hydrology and Earth System Sciences, 18(11): 4437–4452.10.5194/hess-18-4437-2014]Search in Google Scholar
[LI, W., LIN, K., ZHAO. T., LAN, T., CHEN, X., DU, H., CHEN, H. (2019): Risk assessment and sensitivity analysis of flash floods in ungauged basins using coupled hydrologic and hydrodynamic models. Journal of Hydrology, 572: 108–120.10.1016/j.jhydrol.2019.03.002]Search in Google Scholar
[LI, Y., WANG C. (2009): Impacts of Urbanization on Surface Runoff of the Dardenne Creek Watershed, St. Charles County, Missouri. Physical Geography, 30: 556–573.10.2747/0272-3646.30.6.556]Search in Google Scholar
[LI, K., WU, S., DAI, E., XU, Z. (2012): Flood loss analysis and quantitative risk assessment in China. Natural Hazards, 63(2): 737–760.10.1007/s11069-012-0180-y]Search in Google Scholar
[LIU, L. (2018): Application of a Hydrodynamic and Water Quality Model for Inland Surface Water Systems. In: Malcangio, D. [ed.]: Applications in Water Systems Management and Modeling.10.5772/intechopen.74914]Search in Google Scholar
[MARCHI, L., BORGA, M., PRECISO, E., GAUME, E. (2010): Characterisation of selected extreme flash floods in Europe and implications for flood risk management. Journal of Hydrology, 394(1–2): 118–133.10.1016/j.jhydrol.2010.07.017]Search in Google Scholar
[MOSAVI, A., OZTURK, P., CHAU, K. (2018): Flood Prediction Using Machine Learning Models: Literature Review. Water, 10(11): 1536.10.3390/w10111536]Search in Google Scholar
[MASOOD, M., TAKEUCHI, K. (2012): Assessment of flood hazard, vulnerability and risk of mid-eastern Dhaka using DEM and 1D hydrodynamic model. Natural Hazards, 61(2): 757–770.10.1007/s11069-011-0060-x]Search in Google Scholar
[MARK, O., WEESAKUL, S., APIRUMANEKUL, C., AROONNET, S. B., DJORDJEVIĆ, S. (2004): Potential and limitations of 1D modelling of urban flooding. Journal of Hydrology, 299(3–4): 284–299.10.1016/S0022-1694(04)00373-7]Search in Google Scholar
[MERZ, B., THIEKEN, A. H., GOCHT, M. (2007): Flood risk mapping at the local scale: concepts and challenges. In: Begum, S., Stive, M. J. F, Hall, J. W. [eds.]: Flood risk management in Europe, Springer, Berlin, pp. 231–251.10.1007/978-1-4020-4200-3_13]Search in Google Scholar
[MIHU-PINTILIE, A., CIMPIANU, C. I, STOLERIU, C. C., PEREZ, M. N., PAVELUC, L. E.(2019): Using High-Density LiDAR Data and 2D Streamflow Hydraulic Modeling to Improve Urban Flood Hazard Maps: A HEC-RAS Multi-Scenario Approach. Water, 11(9): 1832.10.3390/w11091832]Search in Google Scholar
[MŁYŃSKI, D. (2020): Analysis of Problems Related to the Calculation of Flood Frequency Using Rainfall-Runoff Models: A Case Study in Poland. Sustainability, 12(17): 7187.10.3390/su12177187]Search in Google Scholar
[NOVÁK, P., TOMEK, M. (2015): Prevence a zmírňování následků přívalových povodní ve vztahu k působnosti obcí: metodika. Praha, Výzkumný ústav meliorací a ochrany půdy.]Search in Google Scholar
[NEAL, J. C., FEWTRELL, T. J., BATES, P. D., WRIGHT, N. G. (2010): A comparison of three parallelisation methods for 2D flood inundation models. Environmental Modelling & Software, 25(4): 398–411.10.1016/j.envsoft.2009.11.007]Search in Google Scholar
[NTELEKOS, A. A., GEORGAKAKOS, K. P., KRAJEWSKI, W. F. (2006): On the Uncertainties of Flash Flood Guidance: Toward Probabilistic Forecasting of Flash Floods. Journal of Hydrometeorology, 7(5): 896–915.10.1175/JHM529.1]Search in Google Scholar
[NORBIATO, D., BORGA, M., MERZ, R., BLÖSCHL, G., CARTON, A. (2009): Controls on event runoff coefficients in the eastern Italian Alps. Journal of Hydrology, 375(3–4): 312–325.10.1016/j.jhydrol.2009.06.044]Search in Google Scholar
[O’CONNOR, J. E., GRANT, G. E., COSTA, J. E. (2002): The Geology and Geography of Floods. In: House, P. K., Webb, R. H., Baker, V. R. Levish, D. R. [eds.]: Ancient Floods, Modern Hazards: Principles and Applications of Paleoflood Hydrology, Volume 5. American Geophysical Union, pp. 359–385.10.1029/WS005p0359]Search in Google Scholar
[OPENSTREETMAP® (2019): Data file made by OpenStreetMap contributors [online] [cit. 28.08.2021]. Available at: https://planet.openstreetmap.org]Search in Google Scholar
[PAIVA, R. C. D., BUARQUE, D. C., COLLISCHONN, W., BONNET, M. P., FRAPPART, F., CALMANT, S., MENDES, C. A. B. (2013): Large-scale hydrologic and hydrodynamic modeling of the Amazon River basin, Water Resources Research, 49(3): 1226–1243.10.1002/wrcr.20067]Search in Google Scholar
[PAPAIOANNOU, G., LOUKAS, A., VASILIADES, L., ARONICA, G. T. (2016): Flood inundation mapping sensitivity to riverine spatial resolution and modelling approach. Natural Hazards, 83(1): 117–132.10.1007/s11069-016-2382-1]Search in Google Scholar
[PAPPENBERGER, F., MATGEN, P., BEVEN, K. J., HENRY, J. B., PFISTER, L., DE FRAIPONT, P. (2006): Influence of uncertain boundary conditions and model structure on flood inundation predictions. Advances in Water Resources, 29(10): 1430–1449.10.1016/j.advwatres.2005.11.012]Search in Google Scholar
[PAPROTNY, D., SEBASTIAN, A., MORALES-NÁPOLES, O., JONKMAN, S. N. (2018): Trends in flood losses in Europe over the past 150 years. Nature Communications, 9(1): 1–12.10.1038/s41467-018-04253-1597418329844471]Search in Google Scholar
[PATEL, D. P., RAMIREZ, J. A., SRIVASTAVA, P. K., BRAY, M., HAN, D. (2017): Assessment of flood inundation mapping of Surat city by coupled 1D/2D hydrodynamic modeling: a case application of the new HEC-RAS 5. Natural Hazards, , 89(1): 93–130.10.1007/s11069-017-2956-6]Search in Google Scholar
[PESTANA, R. et al. (2013): Calibration of 2D hydraulic inundation model in the floodplain region of the lower Tagus River. Conference paper: ESA Living Planet Symposium.]Search in Google Scholar
[PETROSELLI, A., VOJTEK, M., VOJTEKOVÁ, J. (2019): Flood mapping in small ungauged basins: a comparison of different approaches for two case studies in Slovakia. Hydrology Research, 50(1): 379–392.10.2166/nh.2018.040]Search in Google Scholar
[PINOS, J., TIMBE L. (2019): Performance assessment of two-dimensional hydraulic models for generation of flood inundation maps in mountain river basins. Water Science and Engineering, 12(1): 11–18.10.1016/j.wse.2019.03.001]Search in Google Scholar
[POUSSIN, J. K., BOTZEN, W. J. W., AERTS, J. C. J. H. (2015): Effectiveness of flood damage mitigation measures: Empirical evidence from French flood disasters. Global Environmental Change, 31: 74–84.10.1016/j.gloenvcha.2014.12.007]Search in Google Scholar
[RUIZ-VILLANUEVA, V., BODOQUE, J. M., DÍEZ-HERRERO, A., EGUIBAR, M. A., PARDO-IGÚZQUIZA, E. (2012): Reconstruction of a flash flood with large wood transport and its influence on hazard patterns in an ungauged mountain basin. Hydrological Processes, 27(24): 3424–3437.10.1002/hyp.9433]Search in Google Scholar
[RUIZ-VILLANUEVA, V., CASTELLET, E. B., DÍEZ-HERRERO, A., BODOQUE, J. M., SÁNCHEZ-JUNY, M. (2014a): Two-dimensional modelling of large wood transport during flash floods. Earth Surface Processes and Landforms, 39(4): 438–449.10.1002/esp.3456]Search in Google Scholar
[RUIZ-VILLANUEVA, V., BODOQUE, J. M., DÍEZ-HERRERO, A., BLADÉ, E. (2014b): Large wood transport as significant influence on flood risk in a mountain village. Natural Hazards, 74(2): 967–987.10.1007/s11069-014-1222-4]Search in Google Scholar
[RUMAN, S., BALL, T., BLACK, A. R., THOMPSON, J. R. (2020): Influence of alternative representations of land use and geology on distributed hydrological modelling results: Eddleston, Scotland. Hydrological Sciences Journal, 66(3): 488–502.10.1080/02626667.2020.1862851]Search in Google Scholar
[RUMAN, S., TICHAVSKÝ, R., ŠILHÁN, K., GRILLAKIS, M. G. (2021): Palaeoflood discharge estimation using dendrogeomorphic methods, rainfall-runoff and hydraulic modelling-a case study from southern Crete. Natural Hazards, 105(2): 1721–1742.10.1007/s11069-020-04373-2]Search in Google Scholar
[SCHUBERT, J. E., SANDERS, B. F. (2012): Building treatments for urban flood inundation models and implications for predictive skill and modeling efficiency. Advances in Water Resources, 41: 49–64.10.1016/j.advwatres.2012.02.012]Search in Google Scholar
[SCHUMM, S. A. (1960): The shape of alluvial channels in relation to sediment type. Washington, USGS.10.3133/pp352B]Search in Google Scholar
[SCHUMM, S. A. (1985): Patterns of Alluvial Rivers. Annual Review of Earth and Planetary Sciences, 13: 5–27.10.1146/annurev.ea.13.050185.000253]Search in Google Scholar
[SENE, K. (2013): Flash Floods: Forecasting and Warning. Springer.10.1007/978-94-007-5164-4]Search in Google Scholar
[SEYOUM, S. D., VOJINOVIC, Z., PRICE, R. K., WEESAKUL, W. (2012): Coupled 1D and Noninertia 2D Flood Inundation Model for Simulation of Urban Flooding. Journal of Hydraulic Engineering, 138(1): 23–24.10.1061/(ASCE)HY.1943-7900.0000485]Search in Google Scholar
[SHARMA, P. J., PATEL, P., JOTHIPRAKASH, V. (2019): Assessment of variability in runoff coefficients and their linkages with physiographic and climatic characteristics of two contrasting catchments. Journal of Water and Climate Change, 10(3): 464–483.10.2166/wcc.2018.139]Search in Google Scholar
[SMITH, D. I. (1994): Flood damage estimation – A review of urban stage-damage curves and loss functions. Water Sa, 20(3): 231–238.]Search in Google Scholar
[SMOLDERS, S., IDES, S., PLANCKE, Y., MEIRE, P., TEMMERMAN, S. (2012): Calibrating discharges in a 2D hydrodynamic model of the Scheldt Estuary: Which parameters can be used and what is their sensitivity. In: Proceeedings of the 10th International Conference on Hydroinformatics (pp. 14–18). Hambrug, Germany.]Search in Google Scholar
[SPELLMAN, P., GULLEY, J., MARTIN, J. B., LOUCKS, J. (2019): The role of antecedent groundwater heads in controlling transient aquifer storage and flood peak attenuation in karst watersheds. Earth Surface Processes and Landforms, 44(1): 77–87.10.1002/esp.4481]Search in Google Scholar
[SRINIVAS, K., WERNER, M., WRIGHT, N. (2009): Comparing forecast skill of inundation models of differing complexity: the case of Upton upon Severn. London, Taylor & Francis Group.10.1201/9780203883020.ch10]Search in Google Scholar
[ŠTĚPÁNKOVÁ, P., DUMBROVSKÝ, M., DRBAL, K. (2017): The Assessment of Level of Flash Floods Threat of Urbanised Areas. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis, 65(2): 519–526.10.11118/actaun201765020519]Search in Google Scholar
[SUBRAMANYA, K. (2008): Engineering Hydrology. 3rd edition. New Dehli, Tata McGraw-Hill Publishing Company Ltd.]Search in Google Scholar
[TENG, J., JAKEMAN, A. J., VAZE, J., CROKE, B. F. W., DUTTA, D., KIM, S. (2017): Flood inundation modelling: A review of methods, recent advances and uncertainty analysis. Environmental Modelling & Software, 90: 201–216.10.1016/j.envsoft.2017.01.006]Search in Google Scholar
[TRPKOSOVA, D., KRASNY, J., PAVLIKOVA, D. (2008): Differences in runoff conditions of crystalline and flysh regions in Moravia and Silesia. Journal of Hydrology and Hydromechanics, 56(3): 201–210.]Search in Google Scholar
[UNDRR (2019): Global Assessment Report on Disaster Risk Reduction. Geneva, Switzerland, United Nations Office for Disaster Risk Reduction.]Search in Google Scholar
[VAN ALPHEN, J., MARTINI, F., LOAT, R., SLOMP, R., PASSCHIER, R. (2009): Flood risk mapping in Europe, experiences and best practices. Journal of Flood Risk Management, 2(4): 285–292.10.1111/j.1753-318X.2009.01045.x]Search in Google Scholar
[VAZE, J., TENG, J., SPENCER, G. (2010): Impact of DEM accuracy and resolution on topographic indices. Environmental Modelling & Software, 25(10): 1086–1098.10.1016/j.envsoft.2010.03.014]Search in Google Scholar
[VINCENDON, B., DUCROCQ, V., NUISSIER, O., VIÉ, B. (2011): Perturbation of convection-permitting NWP forecasts for flash-flood ensemble forecasting. Natural Hazards and Earth System Sciences, 11(5): 1529–1544.10.5194/nhess-11-1529-2011]Search in Google Scholar
[VOJTEK, M., PETROSELLI, A., VOJTEKOVÁ, J., ASGHARINIA, S. (2019): Flood inundation mapping in small and ungauged basins: sensitivity analysis using the EBA4SUB and HEC-RAS modeling approach. Hydrology Research, 50(4): 1002–1019.10.2166/nh.2019.163]Search in Google Scholar
[VOJTEK, M., VOJTEKOVÁ, J. (2016): Flood hazard and flood risk assessment at the local spatial scale: a case study. Geomatics, Natural Hazards and Risk, 7(6): 1973–1992.10.1080/19475705.2016.1166874]Search in Google Scholar
[WANG, Y., LI, Z., TANG, Z., ZENG, G. (2011): A GIS-Based Spatial Multi-Criteria Approach for Flood Risk Assessment in the Dongting Lake Region, Hunan, Central China. Water Resources Management, 25(13): 3465–3484.10.1007/s11269-011-9866-2]Search in Google Scholar
[WINSEMIUS, H. C. et al. (2016): Global drivers of future river flood risk. Nature Climate Change, 6(4): 381–385.10.1038/nclimate2893]Search in Google Scholar
[WISNER, B., BLAIKIE, P., CANNON, T., DAVIS, I. (2004): At Risk: Natural Hazards, People's Vulnerability and Disasters. Routledge.10.4324/9780203974575]Search in Google Scholar
[XIA, X., LIANG, Q., MING, X. (2019): A full-scale fluvial flood modelling framework based on a high-performance integrated hydrodynamic modelling system (HiPIMS). Advances in Water Resources, 132: 103392.10.1016/j.advwatres.2019.103392]Search in Google Scholar
[ZANCHETTA, A. D. L., COULIBALY, P. (2020): Recent Advances in Real-Time Pluvial Flash Flood Forecasting. Water, 12(2): 1–29.10.3390/w12020570]Search in Google Scholar
[ZANON, F. et al. (2010): Hydrological analysis of a flash flood across a climatic and geologic gradient: The September 18, 2007 event in Western Slovenia. Journal of Hydrology, 394(1–2): 182–197.10.1016/j.jhydrol.2010.08.020]Search in Google Scholar
[ZELEŇÁKOVÁ, M., GAŇOVÁ, L., PURCZ, P., SATRAPA, L. (2015): Methodology of flood risk assessment from flash floods based on hazard and vulnerability of the river basin. Natural Hazards, 79(3): 2055–2071.10.1007/s11069-015-1945-x]Search in Google Scholar