Development of regionalized hydrological models in an area with short hydrological observation series

Hoffmann, Lucien; Idrissi, Abdelkhalak El; Pfister, Laurent; Hingray, B.; Guex, F.; Musy, A.; Humbert, Joël; Drogue, Gilles; Leviandier, T.

doi:10.1002/rra.774

Cited by 34 publications

(20 citation statements)

References 5 publications

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“…Four evaluation criteria used by Hoffmann et al (2004) are selected. The model bias for water balance criterion evaluates the ability of the model to reproduce the water balance.…”

Section: Resultsmentioning

confidence: 99%

Hydrological Modeling of Snow Accumulation and Melting on River Basin Scale

Zeinivand

Smedt

2008

Water Resour Manage

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Snowmelt is of importance for many aspects of hydrology, including water supply, erosion and flood control. In this study, snow accumulation and melt are modeled using a distributed hydrological model with two different snowmelt simulation modules. The model is applied for simulating river discharge in the Latyan dam watershed, in the southern part of central Alborz mountain range, Iran. The data consists of 3 years of observed daily precipitation, air temperature, potential evaporation, windspeed and discharge. The discharge data is used for model calibration. When using the temperature index method for snowmelt three parameters need to be calibrated, while for the energy balance approach all parameters are preset and not optimized. The model performance is satisfactory for both methods with efficiencies of more than 80%. In order to show the performance of the model, two interesting snow accumulation and melt periods are discussed in detail. This study shows that the model has great potentiality to simulate the impact of snow accumulation and melt on the hydrological behavior of a river basin.

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“…Four evaluation criteria used by Hoffmann et al (2004) are selected. The model bias for water balance criterion evaluates the ability of the model to reproduce the water balance.…”

Section: Resultsmentioning

confidence: 99%

Hydrological Modeling of Snow Accumulation and Melting on River Basin Scale

Zeinivand

Smedt

2008

Water Resour Manage

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“…This technique produces results similar to those obtained using more precise but slower methods, such as the Shuffled Complex Evolution algorithm by Duan et al (1992). Maximization of the NSE (Nash and Sutcliffe 1970) was used as the objective function and for quantifying the goodness of fit of the simulated discharges with respect to the observed values; in addition, the NSE adapted for high flow conditions (ANSE) (Hoffmann et al 2004) and the RMSE were computed. Barco et al (2008) performed a sensitivity analysis to assess the importance of five parameters in influencing the characteristics of surface runoff (peak flow, peak time and volume) in natural and urban basins.…”

Section: Model Calibrationmentioning

confidence: 96%

Green roof benefits for reducing flood risk at the catchment scale

Masseroni

Cislaghi

2016

Environ Earth Sci

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Among the European countries, Italy is one of the most susceptible to hydrogeological instability events related to the risk of flooding in intensely populated basins, especially inside the Po Valley. A clear example is the Seveso river basin, whose territories are regularly stressed several times per year by flooding events, which in recent years have increased in frequency and intensity. However, it is now impossible to intervene with structural projects aimed at the lamination of flood events, even in modest return periods because of excessive urbanization and continuous residential and industrial expansion. Using extensive and detailed green roof parameters, this study modelled the hydrologic effect of three hypothetical roof greening scenarios at the catchment scale (conversion of 5, 30, and 100 % impervious to green roofs). The modelling of the green roof performances was performed using the Environmental Protection Agency (EPA) Storm Water Management Model (SWMM) and was calibrated over five years of hourly discharge measurements at the closure section of the basin. Hydrologic modelling demonstrated that widespread green roof implementation significantly reduces peak runoff rates and runoff volumes by up to 30 and 35 %, respectively, in the case of 100 % conversion.

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“…To evaluate the specific improvement of the assimilation in low and high flows, we used two indexes as in [62]. The first one is a modified version of the Nash-Sutcliffe criterion and it is basically a calculation of the NS in logarithmic discharges in order to give more weight to low flows.…”

Section: Performance Indexesmentioning

confidence: 99%

Data Assimilation of Satellite Soil Moisture into Rainfall-Runoff Modelling: A Complex Recipe?

et al. 2015

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Data assimilation (DA) of satellite soil moisture (SM) observations represents a great opportunity for improving the ability of rainfall-runoff models in predicting river discharges. Many studies have been carried out so far demonstrating the possibility to reduce model prediction uncertainty by incorporating satellite SM observations. However, large discrepancies can be perceived between these studies with the result that successful DA is not only related to the quality of the satellite observations but can be significantly controlled by many methodological and morphoclimatic factors. In this article, through an experimental study carried out on the Tiber River basin in Central Italy, we explore how the catchment area, soil type, climatology, rescaling technique, observation and model error selection may affect the results of the assimilation and can be the causes of the apparent discrepancies obtained in the literature. The results show that: (i) DA of SM generally improves discharge predictions (with a mean efficiency of about 30%); (ii) unlike catchment area, the soil type and the catchment specific characteristics might have a remarkable influence on the results; (iii) simple rescaling techniques may perform equally well to more complex ones; (iv) an accurate quantification of the model error is paramount for a correct choice of the observation error and, (v) SM temporal variability has a stronger influence than the season itself. On this basis, we advise that DA of SM may be not a simple task and one should carefully test the optimality of the assimilation experiment prior to drawing any general conclusions. OPEN ACCESSRemote Sens. 2015, 7 11404

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Development of regionalized hydrological models in an area with short hydrological observation series

Cited by 34 publications

References 5 publications

Hydrological Modeling of Snow Accumulation and Melting on River Basin Scale

Hydrological Modeling of Snow Accumulation and Melting on River Basin Scale

Green roof benefits for reducing flood risk at the catchment scale

Data Assimilation of Satellite Soil Moisture into Rainfall-Runoff Modelling: A Complex Recipe?

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