Application of a Simple Raster-Based Hydrological Model for Streamflow Prediction in a Humid Catchment with Polder Systems

Water Resources Management

Volumn 25, Issue 2, 2011, Pages 661-676

  Zhao, Guangju ^a   Hörmann, Georg ^a   Fohrer, Nicola ^a   Gao, Junfeng ^b   Li, Hengpeng ^b   Tian, Peng ^c  

^a UNIVERSITY OF KIEL   (Germany)

^b NANJING INSTITUTE OF GEOGRAPHY AND LIMNOLOGY   (China)

^c NORTHWEST A F UNIVERSITY   (China)

Author keywords

Daily discharge; Distributed hydrological model; Polder systems; The PCRaster Xinanjiang (PCR XAJ) model; Xitiaoxi catchment

Indexed keywords

CLIMATE MODELS; EVAPOTRANSPIRATION; FLOOD CONTROL; FLOODS; GROUNDWATER; LAKES; MEAN SQUARE ERROR; RUNOFF; SENSITIVITY ANALYSIS; TOPOGRAPHY; WAVE EQUATIONS;

DAILY DISCHARGE; DISTRIBUTED HYDROLOGICAL MODEL; LAND MANAGEMENT PRACTICES; MODEL SENSITIVITY ANALYSIS; PCRASTER; POTENTIAL EVAPOTRANSPIRATION; ROOT MEAN SQUARE ERRORS; XITIAOXI CATCHMENTS;

CATCHMENTS;

CATCHMENT; CHANNEL FLOW; HYDROLOGICAL MODELING; OVERLAND FLOW; RASTER; RIVER DISCHARGE; SENSITIVITY ANALYSIS; STREAMFLOW;

CHINA; TAIHU BASIN;

EID: 78751566526     PISSN: 09204741     EISSN: None     Source Type: Journal    
DOI: 10.1007/s11269-010-9719-4     Document Type: Article

References (47)

1. Abbott MB, Bathurst JC, Cunge JA, O'Connell PE, Rasmussen J (1986) An introduction to the European Hydrological System-Systeme Hydrologique European, "SHE", 2, Structure of a physically-based, distributed modeling system. J Hydrol 87: 61-77.
2. Arnold JG, Fohrer N (2005) SWAT2000: current capabilities and research opportunities in applied watershed modelling. Hydrol Process 19: 563-572.
3. Bates PD, De Roo APJ (2000) A simple raster-based model for flood inundation simulation. J Hydrol 236: 54-77.
4. Bates PD, Lane SN, Ferguson RI (2005) Computational fluid dynamics: applications in envrionmental hydraulics. Wiley, Chichester.
5. Bergström S (1976) Development and application of a conceptual runoff model for Scandinavian catchments. Department of Water Resources Engineering, Lund Institute of Technology, Bulletin Series A-52, Swedish Meteorological and Hydrological Institute, Norrköping, Sweden.
6. Beven KJ (2001) Rainfall-runoff modeling: a primer. Wiley, West Sussex, pp 217-254.
7. Beven KJ, Kirkby MJ (1979) A physically based variable contributing area model of basin hydrology. Hydrol Sci J 24: 43-69.
8. Chen X, Chen YD, Xu CY (2007) A distributed monthly hydrological model for integerating spatial variations of basin topography and rainfall. Hydrol Process 21: 42-252.
9. Ciarapica L, Todini E (2002) TOPKAPI: a model for the representation of the rainfall-runoff process at different scales. Hydrol Process 16: 207-229.
10. Chow VT, Maidment DR, Larry WM (1988) Applied hydrology. McGraw-Hill, New York, p 627.
11. De Roo APJ (2003) The simulation of two polders for flood protection in the German part of the Oder catchment. European Communities, EUR 20739 EN, Joint Research Centre, Ispra, Italy.
12. De Roo APJ, Offermans RJE, Cremers NHDT (1996) LISEM: a single event physically-based hydrologic and soil erosion model for drainage Basins. II: sensitivity analysis, validation and application. Hydrol Process 10: 1118-1127.
13. De Roo APJ, Wesseling CG, van Deursen WPA (2000) Physically-based river basin modelling within a GIS: the LISFLOOD model. Hydrol Process 14: 1981-1992.
14. Du JK, Xie SP, Xu YP, Xu CY, Singh VP (2007) Development and testing of a simple physically-based distributed rainfall-runoff model for storm runoff simulation in humid forested basins. J Hydrol 336: 334-346.
15. Eagleson PS (1970) Dynamic hydrology. McGraw Hill, New York.
16. Fohrer N, Haverkamp S, Frede HG (2005) Assessment of the effects of land use patterns on hydrologic landscape functions: development of sustainable land use concepts for low mountain range areas. Hydrol Process 19: 659-672.
17. Förster S, Kuhlmann B, Lindenschmidt KE, Bronstert A (2008) Assessing flood risk for a rural detention area. Nat Hazards Earth Syst Sci 8: 311-322.
18. Hessel R, Jetten V, Liu BY, Zhang Y, Stolte J (2003) Calibration of the LISEM model for a small loess Plateau catchment. Catena 54: 235-254.
19. Hesselink AW, Stelling GS, Kwadijk JCJ, Middelkoop H (2003) Inundation of a Dutch river polder, sensitivity analysis of a physically based inundation model using historic data. Water Resour Res 39(9): 1234.
20. Huang S, Rauberg J, Apel H, Lindenschmidt KE (2007) The effectiveness of polder systems on peak discharge capping of floods along the middle reaches of the Elbe River in Germany. Hydrol Earth Syst Sci 11: 1391-1401.
21. Koren V, Reed S, Smith M, Zhang Z (2003) "Combining physically based and conceptual approaches in the development and parameterization of a distributed system." Information from Weather Radar and Distributed Hydrological Modelling (Proceedings of symposium HS03 held during IUGG2003 at Sapporo, Japan, July 2003) IAHS publication, No. 282, 101-108.
22. Lenhart T, Eckhardt K, Fohrer N, Frede HG (2002) Comparison of two different approaches of sensitivity analysis. Phys Chem Earth 27: 645-654.
23. Li ZJ, Ge WZ, Liu JT, Zhao K (2004) Coupling between weather radar rainfall data and a distributed hydrological model for real-time flood forecasting. Hydrol Sci J 49: 945-958.
24. Liu ZY, Martina MLV, Todini E (2005) Flood forecasting using a fully distributed model: application of the TOPKAPI model to the Upper Xixian Catchment. Hydrol Earth Syst Sci 9(4): 347-364.
25. Liu JT, Chen X, Zhang JB, Flury M (2009) Coupling the Xinanjiang model to a kinematic flow model based on digital drainage networks for flood forecasting. Hydrol process 23: 1337-1348.
26. Lu GH, Wu ZY, Wen L, Lin CA, Zhang JY, Yang Y (2008) Real-time flood forecast and flood alert map over the Huaihe River Basin in China using a coupled hydro-meteorological modeling system. Sci China Ser, E-Technol Sci 51: 1049-1063.
27. Nash JE, Sutcliffe JV (1970) River flow forecasting through conceptual models, part I: A discussion of principles. J Hydrol 10(3): 282-290.
28. Neitsch SL, Arnold JG, Kiniry JR, Williams JR, King KW (2002) Soil and Water Assessment Tool Theoretical Documentation. Version 2000. Texas Water Resources Institute, College Station, Texas. TWRI Report, TR-191.
29. Pullar D, Springer D (2000) Towards integrating GIS and catchment models. Environ Model Softw 15: 451-459.
30. Robinson JS, Sivapalan M (1995) Catchment-scale runoff generation model by aggregation and similarity analysis. In: Kalma JD, Sivapalan M (eds) Scale issues in hydrological modeling. Wiley, New York, pp 311-330.
31. Schuol J, Abbaspour KC, Srinivasan R, Yang H (2008) Estimation of freshwater availability in the West African sub-continent using the SWAT hydrologic model. J Hydrol 352(1-2): 30-49.
32. Sheikh V, Visser S, Stroosnijder L (2009) A simple model to predict soil moisture: Briding Event and Continuous Hydrological (BEACH) modelling. Environ Model Softw 24: 542-556.
33. Singh VP, Woolhiser DA (1996) A nonlinear kinematic wave model for watershed surface runoff. J Hydrol 31: 221-243.
34. Smith RE, Goodrich DC, Woolhiser DA, Unkrich CL (1995) KINEROS - A KINematic Runoff and EROSion Model. In: Singh VP (ed) Computer models of watershed hydrology. Water Resources Publications, Highlands Ranch, pp 697-732.
35. Todini E (1996) The ARNO rainfall-runoff model. J Hydrol 175: 339-382.
36. Todini E, Ciarapica L (2001) The TOPKAPI model. In: Singh VP (ed) Mathematical models of large watershed hydrology, Chapter 12. Water Resources Publications, Highlands Ranch.
37. Uhlenbrook S, Roser S, Tilch N (2004) Hydrological process representation at the meso-scale: the potential of a distributed, conceptual catchment model. J Hydrol 291: 278-296.
38. van der Knijff J, De Roo APJ (2008) LISFLOOD Distributed water balance and flood simulation model, Revised user manual, Office for Official Publications of the European Communities, Luxembourg, EUR 22166 EN/2.
39. van Deursen WPA (1995) Geographical information systems and dynamic models: development and application of a prototype spatial modelling language. Netherlands Geographic Studies, Issue 190.
40. Wang JQ, Zhang XY, Lu ZH (2004) Digital hydrological model of Qinhuai River basin and its application. Shuili Xuebao 4: 1-7. (in Chinese).
41. Wesseling CG, Karssenberg DJ, Burrough PA, van Deursen WPA (1996) Integrated dynamic environmental models in GIS: the development of a dynamic modelling language. Trans GIS 1-1: 40-48.
42. Xu LG, Zhang Q, Li HP, Viney NR, Xu JT, Liu J (2007) Modeling of surface runoff in Xitiaoxi catchment, China. Water Resour Manage 21(8): 1313-1323. doi: 10. 1007/s11269-006-9083-6.
43. Yao C, Li ZJ, Bao HJ, Yu ZB (2009) Application of developed Grid-Xinanjiang model to Chinese watersheds for flood forecasting purpose. J Hydrol Eng. doi: 10. 1061/(ASCE) HE. 1943-5584. 0000067.
44. Zhang Q, Werner AD (2009) Integrated surface-subsurface modeling of Fuxianhu Lake catchment, southwest China. Water Resour Manage 23: 2189-2204. doi: 10. 1007/s11269-008-9377-y.
45. Zhao RJ (1984) Water hydrological modelling - Xinanjiang Model and Shanbei Model. China Water Resources and Hydropower Press, Beijing (in Chinese).
46. Zhao RJ (1992) The Xinanjiang model applied in China. J Hydrol 135: 371-381.
47. Zhao RJ, Zhuang YL, Fang LR, Liu XR, Zhang QS (1980) The Xinanjiang model. Hydrological Forecasting Proceedings Oxford Symposium. IASH 129: 351-356.