Parameter estimation in distributed hydrological catchment modelling using automatic calibration with multiple objectives

A consistent framework for parameter estimation in distributed hydrological catchment modelling using automatic calibration is formulated. The framework focuses on the different steps in the estimation process from model parameterisation and selection of calibration parameters, formulation of calibr...

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Bibliographic Details
Published in:	Advances in water resources Vol. 26; no. 2; pp. 205 - 216
Main Author:	Madsen, Henrik
Format:	Journal Article Conference Proceeding
Language:	English
Published:	Oxford Elsevier Ltd 01.02.2003 Elsevier Science
Subjects:	algorithms Automatic calibration Denmark Distributed model Earth sciences Earth, ocean, space estimation Exact sciences and technology Hydrogeology Hydrological modelling Hydrology. Hydrogeology MIKE SHE Multiple objectives Parameter estimation runoff simulation models water table watershed hydrology watersheds Denmark Scandinavia Hydrological modelling Distributed model Parameter estimation Multiple objectives Automatic calibration MIKE SHE algorithms Europe simulation ground water water table runoff drainage basins hydrological modeling optimization calibration
ISSN:	0309-1708, 1872-9657
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Abstract	A consistent framework for parameter estimation in distributed hydrological catchment modelling using automatic calibration is formulated. The framework focuses on the different steps in the estimation process from model parameterisation and selection of calibration parameters, formulation of calibration criteria, and choice of optimisation algorithm. The calibration problem is formulated in a general multi-objective context in which different objective functions that measure individual process descriptions can be optimised simultaneously. Within this framework it is possible to tailor the model calibration to the specific objectives of the model application being considered. A test example is presented that illustrates the use of the calibration framework for parameter estimation in the MIKE SHE integrated and distributed hydrological modelling system. A significant trade-off between the performance of the groundwater level simulations and the catchment runoff is observed in this case, defining a Pareto front with a very sharp structure. The Pareto optimum solution corresponding to a proposed balanced aggregated objective function is seen to provide a proper balance between the two objectives. Compared to a manual expert calibration, the balanced Pareto optimum solution provides generally better simulation of the runoff, whereas virtually similar performance is obtained for the groundwater level simulations.
AbstractList	A consistent framework for parameter estimation in distributed hydrological catchment modelling using automatic calibration is formulated. The framework focuses on the different steps in the estimation process from model parameterisation and selection of calibration parameters, formulation of calibration criteria, and choice of optimisation algorithm. The calibration problem is formulated in a general multi-objective context in which different objective functions that measure individual process descriptions can be optimised simultaneously. Within this framework it is possible to tailor the model calibration to the specific objectives of the model application being considered. A test example is presented that illustrates the use of the calibration framework for parameter estimation in the MIKE SHE integrated and distributed hydrological modelling system. A significant trade-off between the performance of the groundwater level simulations and the catchment runoff is observed in this case, defining a Pareto front with a very sharp structure. The Pareto optimum solution corresponding to a proposed balanced aggregated objective function is seen to provide a proper balance between the two objectives. Compared to a manual expert calibration, the balanced Pareto optimum solution provides generally better simulation of the runoff, whereas virtually similar performance is obtained for the groundwater level simulations.
Author	Madsen, Henrik
Author_xml	– sequence: 1 givenname: Henrik surname: Madsen fullname: Madsen, Henrik email: hem@dhi.dk organization: DHI Water and Environment, Agern Allé 11, DK-2970 Hørsholm, Denmark
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Snippet	A consistent framework for parameter estimation in distributed hydrological catchment modelling using automatic calibration is formulated. The framework...
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SubjectTerms	algorithms Automatic calibration Denmark Distributed model Earth sciences Earth, ocean, space estimation Exact sciences and technology Hydrogeology Hydrological modelling Hydrology. Hydrogeology MIKE SHE Multiple objectives Parameter estimation runoff simulation models water table watershed hydrology watersheds
Title	Parameter estimation in distributed hydrological catchment modelling using automatic calibration with multiple objectives
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