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Modelling of Hydrological Processes in the Narew Catchment pp 15–41Cite as

Multi-Site Calibration and Validation of the Hydrological Component of SWAT in a Large Lowland Catchment

Part of the Geoplanet: Earth and Planetary Sciences book series (GEPS)

Abstract

This study describes an application of a hydrological component of the catchment model, Soil and Water Assessment Tool (SWAT) in the Narew basin (ca. 28,000 km2) situated in the north-east of Poland. The main objective was to perform a multi-site (spatially distributed) calibration and validation of SWAT using daily observed flows from 23 gauging stations as well as to assess the model’s capability to perform reliable simulations at spatial scales that were smaller than those in the calibration phase. A detailed description of the model configuration for the Narew basin upstream from Zambski Kościelne gauge has been given. Building a SWAT project for a large-scale application appeared to be a demanding task, with the most critical part of preparing soil input data. Sensitivity analysis performed using a LH-OAT method indicated which parameters should be used in autocalibration. The ParaSol tool allowed to find the best parameter values from 8D parameter space in 11 calibration areas. The calibrated model generally performed well, with average Nash–Sutcliffe Efficiency for daily data equal to 0.68 for calibration period and 0.57 for validation period. SWAT correctly conserved the mass balance in different parts of the catchment as well as at the main outlet. The model results were significantly better in large basins than in small basins. Spatial validation performed at 12 independent catchments ranging in size from 355 to 1,657 km2 revealed that adapted SWAT model should rather not be used in the Narew basin catchments smaller than ca. 600 km2. It is believed that ensuring reliability of SWAT results at smaller spatial scales, which would be of interest to decision-makers, would require providing better input data and in particular using significantly more precipitation stations.

Keywords

  • Hydrologic Response Unit
  • Hydrological Component
  • Manual Calibration
  • Catchment Model
  • Temporal Validation

These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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Notes

  1. 1.

    http://www.unesco-ihe.org/Flood-Management-Education-Platform/Flood-Modelling-for-Management2

  2. 2.

    https://www.card.iastate.edu/swat_articles/ as for 21-Oct-2010.

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Acknowledgments

The authors gratefully acknowledge financial support for the project Water Scenarios for Europe and Neighbouring States (SCENES) from the European Commission (FP6 contract 036822). We would also like to thank two referees for their constructive comments and improvement of English and Prof. Raghavan Srinivasan from Texas A&M University for clarifying many SWAT-related issues.

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Authors and Affiliations

  1. Department of Hydraulic Engineering, Warsaw University of Life Sciences, Nowoursynowska Str. 159, 02-787, Warszawa, Poland

    Mikołaj Piniewski & Tomasz Okruszko

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  1. Mikołaj Piniewski
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  2. Tomasz Okruszko
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Correspondence to Mikołaj Piniewski .

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Editors and Affiliations

  1. SGGW, Dept. of Engineering and, Warsaw University of Life Sciences, Nowoursynowska 166, Warsaw, 02-787, Poland

    Dorota Świątek

  2. SGGW, Dept. of Engineering, Warsaw University of Life Sciences, Nowoursynowska 166, Warsaw, 02-787, Poland

    Tomasz Okruszko

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Piniewski, M., Okruszko, T. (2011). Multi-Site Calibration and Validation of the Hydrological Component of SWAT in a Large Lowland Catchment. In: Świątek, D., Okruszko, T. (eds) Modelling of Hydrological Processes in the Narew Catchment. Geoplanet: Earth and Planetary Sciences. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-19059-9_2

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