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Assimilation of meteorological and remote sensing data for snowmelt runoff forecasting

A versatile data assimilation scheme for remote sensing snow cover products and meteorological data was developed, aimed at operational use for short-term runoff forecasting. Spatial and temporal homogenisation of the various input data sets is carried out, including meteorological point measurement...

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Published in:	Remote sensing of environment 2008-04, Vol.112 (4), p.1408-1420
Main Authors:	Nagler, Thomas, Rott, Helmut, Malcher, Petra, Müller, Florian
Format:	Article
Language:	English
Subjects:	Data assimilation Optical sensors Runoff forecasting SAR Snow cover mapping Snowmelt runoff modelling
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creator	Nagler, Thomas Rott, Helmut Malcher, Petra Müller, Florian
description	A versatile data assimilation scheme for remote sensing snow cover products and meteorological data was developed, aimed at operational use for short-term runoff forecasting. Spatial and temporal homogenisation of the various input data sets is carried out, including meteorological point measurements from stations, numerical weather predictions, and snow maps from satellites. The meteorological data are downscaled to match the scale of the snow products, derived from optical satellite images of MODIS and from radar images of Envisat ASAR. Snow maps from SAR and optical imagery reveal systematic differences which need to be compensated for use in snowmelt models. We applied a semi-distributed model to demonstrate the use of satellite snow cover data for short-term runoff forecasting. During the snowmelt periods 2005 and 2006 daily runoff forecasts were made for the drainage basin Ötztal (Austrian Alps) for time lags up to 6 days. Because satellite images were obtained intermittently, prognostic equations were applied to predict the daily snow cover extent for model update. Runoff forecasting uncertainty is estimated by using not only deterministic meteorological predictions as input, but also 51 ensemble predictions of the EPS system of the European Centre for Medium Range Weather Forecast. This is particularly important for water management tasks, because meteorological forecasts are the main error source for runoff prediction, as confirmed by simulation studies with modified input data from the various sources. Evaluation of the runoff forecasts reveals good agreement with the measurements, confirming the usefulness of the selected data processing and assimilation scheme for operational use.
doi_str_mv	10.1016/j.rse.2007.07.006
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Runoff forecasting uncertainty is estimated by using not only deterministic meteorological predictions as input, but also 51 ensemble predictions of the EPS system of the European Centre for Medium Range Weather Forecast. This is particularly important for water management tasks, because meteorological forecasts are the main error source for runoff prediction, as confirmed by simulation studies with modified input data from the various sources. 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issn	0034-4257 1879-0704
language	eng
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source	ScienceDirect Freedom Collection 2022-2024
subjects	Data assimilation Optical sensors Runoff forecasting SAR Snow cover mapping Snowmelt runoff modelling
title	Assimilation of meteorological and remote sensing data for snowmelt runoff forecasting
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