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Water Resources Management

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01.09.2012

The Value of Snow Depletion Forecasting Methods Towards Operational Snowmelt Runoff Estimation Using MODIS and Numerical Weather Prediction Data

verfasst von: Aynur Şensoy, Gökçen Uysal

Erschienen in: Water Resources Management | Ausgabe 12/2012

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Abstract

Forecasting streamflow mainly due to snowmelt in the mountainous eastern part of Turkey is important in terms of effective management of water resources at the headwaters of Euphrates River, where large dam reservoirs are located. Monitoring Snow Covered Area (SCA) and modeling snowmelt forms the backbone of the forecasting studies as the snowmelt dominating runoff constitutes approximately 2/3 of total annual volume of runoff during spring and early summer. Two main motivations of the study are; firstly, to assess the methodologies to forecast SCA using Moderate Resolution Imaging Spectroradiometer (MODIS) data and derive Snow Depletion Curve (SDC) for each elevation zone. Secondly, to forecast 1 day ahead daily discharges using the derived SDCs and Numerical Weather Prediction (NWP) data corrected specifically for the area. The Upper Euphrates Basin (10,275 km²) is selected as the pilot basin and MODIS daily snow cover products are analyzed for the snowmelt season. Four different methodologies are proposed and assessed to forecast SDCs; simple averaging, temperature based, stochastic modeling and probabilistic approach. SDCs are derived for the water years 2006–2010, 4 years data are used to derive the equations of the methodologies and 1 year is used to verify their skills. Forecasting discharges 1 day ahead with Snowmelt Runoff Model using NWP data is the second part of the study. Impact of forecasted SDCs with different methodologies is examined with the model. Model applications provide promising results both for the forecasting of SCA and runoff with an overall Model Efficiency higher than 0.60 and 0.85, respectively.

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Andreadis KM, Lettenmaier DP (2006) Assimilating remotely sensed snow observations into a macroscale hydrology model. Adv Water Resour 29:872–886. doi:10.1016/j.advwatres.2005.08.004 CrossRef

Bales RC, Molotch NP, Painter TH, Dettinger MD, Rice R, Dozier J (2006) Mountain hydrology of the Western United States. Water Resour Res 42. doi:10.1029/2005wr004387

Bitner D, Carroll T, Cline D, Romanov P (2002) An assessment of the differences between three satellite snow cover mapping techniques. Hydrol Process 16:3723–3733. doi:10.1002/Hyp.1231 CrossRef

Box GEP, Jenkins GM (1970) Time series analysis: Forecasting and control: San Francisco; Holden-Day

Clark MP, Slater AG, Barrett AP, Hay LE, McCabe GJ, Rajagopalan B, Leavesley GH (2006) Assimilation of snow covered area information into hydrologic and land-surface models. Adv Water Resour 29:1209–1221. doi:10.1016/j.advwatres.2005.10.001 CrossRef

Dressler KA, Leavesley GH, Bales RC, Fassnacht SR (2006) Evaluation of gridded snow water equivalent and satellite snow cover products for mountain basins in a hydrologic model. Hydrol Process 20:673–688. doi:10.1002/Hyp.6130 CrossRef

Ferguson RI (1999) Snowmelt runoff models. Progr Phys Geogr 23(2):205–227

Forsythe N, Fowler HJ, Kilsby CG, Archer DR (2012) Opportunities from remote sensing for supporting water resources management in village/valley scale catchments in the upper Indus basin. Water Resour Manag 26:845–871. doi:10.1007/s11269-011-9933-8 CrossRef

Gafurov A, Bárdossy A (2009) Cloud removal methodology from MODIS snow cover product. Hydrol Earth Syst Sci 13(7):1361–1373CrossRef

Garen DC, Johnson GL, Hanson CL (1994) Mean areal precipitation for daily hydrologic modeling in mountainous regions. Water Resour Bull 30(3):481–491CrossRef

Gómez-Landesa E, Rango A (2002) Operational snowmelt runoff forecasting in the Spanish Pyrenees using the snowmelt runoff model. Hydrol Process 16:1583–1591. doi:10.1002/Hyp.1022 CrossRef

Hall DK, Martinec J (1985) Remote sensing of ice and snow. Chapman and Hall Ltd, London, p 189CrossRef

Hall DK, Riggs GA, Salomonson VV, DiGirolamo NE, Bayr KJ (2002) MODIS snow-cover products. Remote Sens Environ 83:181–194CrossRef

Jain S, Lall U (2000) Magnitude and timing of annual maximum floods: trends and large-scale climatic associations for the Blacksmith Fork River, Utah. Water Resour Res 36(12):3641–3651CrossRef

Jain SK, Goswami A, Saraf AK (2009) Role of elevation and aspect in snow distribution in western Himalaya. Water Resour Manag 23:71–83. doi:10.1007/s11269-008-9265-5 CrossRef

Jain SK, Goswami A, Saraf AK (2010a) Snowmelt runoff modelling in a Himalayan basin with the aid of satellite data. Int J Remote Sens 31(24):6603–6618CrossRef

Jain SK, Goswami A, Saraf AK (2010b) Assessment of snowmelt runoff using remote sensing and effect of climate change on runoff. Water Resour Manag 24(9):1763–1777. doi:10.1007/s11269-009-9523-1 CrossRef

Jain SK, Thakural LN, Singh RD, Lohani AK, Mishra SK (2011) Snow cover depletion under changed climate with the help of remote sensing and temperature data. Nat Hazards 58(3):891–904. doi:10.1007/s11069-010-9696-1 CrossRef

Kaya HI (1999) Application of snowmelt runoff model using remote sensing and GIS. Msc. Thesis, Middle East Technical University, Turkey

Klein AG, Barnett AC (2003) Validation of daily MODIS snow cover maps of the Upper Rio Grande River Basin for the 2000–2001 snow year. Remote Sens Environ 86:162–176. doi:10.1016/S0034-4257(03)00097-X CrossRef

Lee SW, Klein AG, Over TM (2005) A comparison of MODIS and NOHRSC snow-cover products for simulating stream flow using the Snowmelt Runoff Model. Hydrol Process 19(15):2951–2972. doi:10.1002/Hyp.5810 CrossRef

Martinec J (1975) Snowmelt-runoff model for stream flow forecasts. Nord Hydrol 6:145–154

Maurer EP, Rhoads JD, Dubayah RO, Lettenmaier DP (2003) Evaluation of the snow-covered area data product from MODIS. Hydrol Process 17(1):59–71. doi:10.1002/Hyp.1193 CrossRef

McGuire M, Wood AW, Hamlet AF, Lettenmaier DP (2006) Use of satellite data for streamflow and reservoir storage forecasts in the snake river basin. J Water Res Pl-Asce 132(2):97–110. doi:10.1061/(Asce)0733-9496 CrossRef

Nash JC, Sutcliffe JV (1970) River flow forecasting through conceptual models part I—a discussion of principles. J Hydrol 10(3):282–290CrossRef

Parajka J, Blöschl G (2006) Validation of MODIS snow cover images over Austria. Hydrol Earth Syst Sci 10(5):679–689CrossRef

Parajka J, Blöschl G (2008a) The value of MODIS snow cover data in validating and calibrating conceptual hydrologic models. J Hydrol 358(3–4):240–258. doi:10.1016/j.jhydrol.2008.06.006 CrossRef

Parajka J, Blöschl G (2008b) Spatio-temporal combination of MODIS images—potential for snow cover mapping. Water Resour Res 44(3), 10.1029/2007WR006204

Pu ZX, Xu L, Salomonson VV (2007) MODIS/Terra observed seasonal variations of snow cover over the Tibetan Plateau. Geophys Res Lett 34(6), 10.1029/2007GL029262

Rango A, Martinec J (1979) Application of a snowmelt-runoff model using landsat data. Nord Hydrol 10:225–238. doi:10.2166/nh.1979.015

Rango A, Vankatwijk V (1990) Development and testing of a snowmelt-runoff forecasting technique. Water Resour Bull 26:135–144CrossRef

Richer EE (2009) Snowmelt runoff analysis and modelling for the upper cache La Poudre River basin, Colorado. MsS Thesis, Colorado State University Fort Collins, USA

Seidel K, Martinec J (2004) Remote sensing in snow hydrology. Springer and Praxis, Chichester

Şensoy A, Şorman AA, Tekeli AE, Şorman AÜ, Garen DC (2006) Point-scale energy and mass balance snowpack simulations in the upper Karasu basin, Turkey. Hydrol Process 20(4):899–922. doi:10.1002/Hyp.6120 CrossRef

Şensoy A, Uysal G, Şorman AA, Şorman AÜ (2010) Topographic effects on snow depletion curves of upper Euphrates River Basin, Turkey. Paper presented at the BALWOIS 2010 on water observation and information systems, Ohrid, FYROM, 25–29 May 2010

Simic A, Fernandes R, Brown R, Romanov P, Park W (2004) Validation of VEGETATION, MODIS, and GOES plus SSM/I snow-cover products over Canada based on surface snow depth observations. Hydrol Process 18(6):1089–1104. doi:10.1002/Hyp.5509 CrossRef

Singh P, Bengtsson L, Berndtsson R (2003) Relating air temperatures to the depletion of snow covered area in a Himalayan basin. Nord Hydrol 34(4):267–280

Şorman AA, Yamankurt E (2011) Modified satellite products on snow covered area in upper Euphrates basin, Turkey. Geophysical Research Abstracts Vol. 13: EGU2011-7887. European Geosciences Union, General Assembly 2011, Vienna, 03–08 April 2011

Şorman AA, Şensoy A, Tekeli AE, Şorman AÜ, Akyürek Z (2009) Modelling and forecasting snowmelt runoff process using the HBV model in the eastern part of Turkey. Hydrol Process 23(7):1031–1040. doi:10.1002/Hyp.7204 CrossRef

Şorman AÜ, Akyürek Z, Şensoy A, Şorman AA, Tekeli AE (2007) Commentary on comparison of MODIS snow cover and albedo products with ground observations over the mountainous terrain of Turkey. Hydrol Earth Syst Sci 11:1353–1360CrossRef

Tekeli AE (2005) Operational hydrological forecasting of snowmelt runoff by remote sensing and geographic information systems integration. PhD Thesis, Middle East Technical University, Turkey

Tekeli AE, Akyurek Z, Şensoy A, Şorman AA, Şorman AÜ (2005a) Using MODIS snow cover maps in modeling snowmelt runoff process in the eastern part of Turkey. Remote Sens Environ 97:216–230. doi:10.1016/j.rse.2005.03.013 CrossRef

Tekeli AE, Akyürek Z, Şorman AA, Şensoy A, Şorman AÜ (2005b) Modelling the temporal variation in snow-covered area derived from satellite images for simulating/forecasting of snowmelt runoff in Turkey. Hydrolog Sci J 50(4):669–682CrossRef

Tong J, Dery SJ, Jackson PL (2009) Topographic control of snow distribution in an alpine watershed of western Canada inferred from spatially-filtered MODIS snow products. Hydrol Earth Syst Sci 13:319–326CrossRef

Wang XW, Xie HJ, Liang TG, Huang XD (2009) Comparison and validation of MODIS standard and new combination of Terra and Aqua snow cover products in northern Xinjiang, China. Hydrol Process 23(3):419–429. doi:10.1002/Hyp.7151 CrossRef

WinSRM (2008) WinSRM users manual. Available at: http://aces.nmsu.edu/pubs/research/weather_climate/SRMSpecRep100.pdf Accessed on 1^thAugust 2011

Zhou XB, Xie HJ, Hendrickx JMH (2005) Statistical evaluation of remotely sensed snow-cover products with constraints from streamflow and SNOTEL measurements. Remote Sens Environ 94:214–231. doi:10.1016/j.rse.2004.10.007 CrossRef

Titel: The Value of Snow Depletion Forecasting Methods Towards Operational Snowmelt Runoff Estimation Using MODIS and Numerical Weather Prediction Data
verfasst von: Aynur Şensoy
Gökçen Uysal
Publikationsdatum: 01.09.2012
Verlag: Springer Netherlands
Erschienen in: Water Resources Management / Ausgabe 12/2012
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI: https://doi.org/10.1007/s11269-012-0079-0

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