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Comparison and Evaluation of the Inundation Areas by Levee Breaching using LISFLOOD
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  • Journal title : Journal of Wetlands Research
  • Volume 16, Issue 3,  2014, pp.383-392
  • Publisher : Korean Wetlands Society
  • DOI : 10.17663/JWR.2014.16.3.383
 Title & Authors
Comparison and Evaluation of the Inundation Areas by Levee Breaching using LISFLOOD
Choi, Cheon Kyu; Choi, Yun Seok; Kim, Kyung Tak;
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 Abstract
The purpose of this study is to simulate inundation and evaluate the applicability of LISFLOOD model to the streams in South Korea by comparing with the inundation map using FLUMEN. The suggested levee breaching scenarios were applied to the LISFLOOD model, and the results obtained from scenarios were evaluated. The modeling results using LISFLOOD by appling the levee breaching scenarios showed 0.2% ~ 42% relative error with FLUMEN model in inundation area. But the relative error of maximum inundation area by overlapping all the flood analysis results from levee breaching scenarios such as the way making flood risk map was approximately 1.2% between two models. Meanwhile, LISFLOOD model was easy to construct input data, DEM as topographic data and discharge hydrograph as upper boundary conditions. And computing time of LISFLOOD was shorter than FLUMEN. Therefore LISFLOOD model can be applied usefully in the region that needs immediate inundation modeling.
 Keywords
LISFLOOD;flood inundation map;flood analysis;FLUMEN;
 Language
Korean
 Cited by
1.
하천공간 확보를 위한 홍수의 공간적 범람 분석,최천규;김주훈;김규호;김길호;

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Application of the LISFLOOD-FP model for flood stage prediction on the lower mankyung river, Journal of Korea Water Resources Association, 2016, 49, 6, 459  crossref(new windwow)
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Spatial Analysis of Flood Inundation for Ensuring Stream Space, Journal of the Korean Society of Civil Engineers, 2015, 35, 2, 341  crossref(new windwow)
 References
1.
Bae, YH, Koh, DK and Cho, YS (2005). Numerical simulations of flood inundations with FLUMEN, J. of Korea Water Resources Association, 14(4), pp. 355-364. [Korean Literature]

2.
Baldassarre, GD, Schumann, G, Bates, PD, Freer, JE and Beven, KJ (2010). Flood-plain mapping: a critical discussion of deterministic and probabilistic approaches, Hydrological Sciences Journal, 55(3), pp. 364-376. crossref(new window)

3.
Bates, PD. and De Roo, APJ (2000). A simple raster-based model for flood inundation simulation, J. of Hydrology, 236(1-2), pp. 54-77. crossref(new window)

4.
Bates, PD, Horritt, MS and Fewtrell, TJ (2010). A simple inertial formulation of the shallow water equations for efficient two-dimensional flood inundation modelling, J. of Hydrology, 387, pp. 33-45. crossref(new window)

5.
Beckers, B and Schutt, B (2013). The elaborate floodwater harvesting system of ancient Resafa in Syria-Construction and reliability, J. of Arid Environments, 96, pp. 31-47. crossref(new window)

6.
Cho, WH, Han, KY and Ahn, KH (2010). Flood risk mapping with FLUMEN model application, J. of Korean Society of Civil Engineers, 30(2B), pp. 169-177. [Korean Literature]

7.
Choi, CK, Choi, YS and Kim, KT (2013). Analysis of flood inundation using LiDAR and LISFLOOD model, J. of the Korean Association of Geographic Information Studies, 16(4), pp. 1-15. [Korean Literature]

8.
Coulthard, TJ, Hicks, DM and Van De Wiel, MJ (2007). Cellular modelling of river catchments and reaches: advantages, limitations and prospects, Geomorphology, 90, pp. 192-207. crossref(new window)

9.
Coulthard, TJ, Neal, JC, Bates, PD, Ramirez, J, De Almeida, GAM and Hancock, GR (2013). Integrating the LISFLOOD-FP 2D hydrodynamic model with the CAESAR model: inplications for modelling landscape evolution, Earth Surf. Process. Landforms, 38, pp. 1897-1906. crossref(new window)

10.
Dankers, R, Christensen, OB, Feyen L and Kalas, M (2007). Evaluation of very high-resolution climate model data for simulating flood hazards in the Upper Danube Basin, J. of Hydrology, 347, pp. 319-331. crossref(new window)

11.
De Roo, APJ, Wesseling, CG and Van Deursen, WPA (2000). Physically based river basin modelling within a GIS: the LISFLOOD model, Hydrol. Processes, 14, pp. 1981-1992. crossref(new window)

12.
Horritt, MS and Bates, PD (2002). Evaluation of 1D and 2D numerical models for predicting river flood inundation, J. of Hydrology, 268, pp. 87-99. crossref(new window)

13.
Horritt, MS (2006). A methodology for the validation of uncertain flood inundation models, J. of Hydrology, 326, pp. 153-165. crossref(new window)

14.
Hunter, NM, Bates, PD, Horritt, MS and Wilson, MD (2007). Simple spatially-distributed models for predicting flood inundation: a review, Geomorphology, 90, pp. 208-225. crossref(new window)

15.
Jung, YH., Yeo, KD, Kim, SY and Lee, SO (2013). The effect of uncertainty in roughness and discharge on flood inundation mapping, J. of Korean Society of Civil Engineers, 33(3), pp. 937-945. [Korean Literature] crossref(new window)

16.
Kang, HS, Cho, SY and Song, YI (2011). A study on flood storage plans of farmlands for extreme flood reduction, J. of Korea Water Resources Association, 44(10), pp. 787-795. [Korean Literature] crossref(new window)

17.
Kang, SM, Park, MJ, Kim, SH and Kim, SJ (2007). A study on the mitigation of inundation damage using flood inundation analysis model FLUMEN For the part of Jinwicheon reach-, J. of Korean Society of Civil Engineers, 27(6B), pp. 583-590. [Korean Literature]

18.
KEI(Korea Environment Institute). (2009). Fundamental research on costal landward boundaries integrated flood forcating methods according to the climate change. [Korean Literature]

19.
Kim, JH, Lee, SO, Yoon, KS and Cho, YS (2008). Application of a two-dimensional flood inundation model based on quadtree grid, J. of Korean Society of Hazard Mitigation, 8(3), pp. 129-136. [Korean Literature]

20.
Lee, GH, Park, KW, Yu, WS, Jung, KS and Jang, CL (2011). A study on flood damage estimation using DEM-based flood inundation model and MD-FDA, J. of Korean Society of Hazard Mitigation, 11(5), pp. 327-336. [Korean Literature] crossref(new window)

21.
Lee, GS and Choi, YW (2010). The simulation of flood inundation of Namdae stream with GIS-based FLUMEN model, J. of Korea Spatial Information Society, 18(2), pp. 25-34. [Korean Literature]

22.
Lee, JS, Moon, CG, Kim, SD, Cho, SG and Shin, SC (2012). A study on construction techniques of river topography for flood inundation analysis, J. of the Korean Geo-Environmental Society, 13(5), pp. 59-68. [Korean Literature]

23.
MLTM(Minstry of Land, Transport and Maritime). (2008). Guidance on flood risk mapping.

24.
MLTM(Minstry of Land, Transport and Maritime). (2011). Cheonmicheon(Riv.) river maintenance master plan report.

25.
MLTM(Minstry of Land, Transport and Maritime). (2012). Flood risk mapping report in the Han river watersheds(3rd).

26.
Pappenberger, F, Frodsham, K, Beven, K, Romanowicz, R and Matgen, P (2007). Fuzzy set approach to calibrating distributed flood inudnation models using remote sensing observation, Hydrology and Earth System Sciences, 11(2), pp. 739-752. crossref(new window)

27.
Park, SJ, Choi, HG, Huh, YH and Han, KY (2011). Establishment and application of 2-dimensional flood inundation analysis system by the collaboration of river and lowland in Nam river basin, J. of Korean Society of Hazard Mitigation, 11(6), pp. 237-247. [Korean Literature]

28.
Shim, JM and Lee, SB (2006). The study of flood simulations using LiDAR data, J. of Korean Society for Geographical Information System, 14(4), pp. 53-60. [Korean Literature]