Streamflow Modelling: A Primer on Applications, Approaches and Challenges

Bourdin, Dominique R.; Fleming, Sean W.; Stull, Roland B.

doi:10.1080/07055900.2012.734276

Cited by 79 publications

(41 citation statements)

References 253 publications

(349 reference statements)

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“…In many cases, the complicated interaction in the hydroclimatic system cannot be characterized by linear models. The Artificial Intelligence (AI) (or machine learning, soft computing) models, including Artificial Neural Network (ANN), Fuzzy Logic (FL), Support Vector Regression (SVR) or Support Vector Machine (SVM), Genetic Algorithm (GA) or Genetic Programming (GP), and wavelet transformation, can be used to model complex interactions of hydroclimatic variables for a variety of applications (Bourdin et al, 2012;Fahimi et al, 2016;Nourani et al, 2014;Rhee & Im, 2017;Wang, Chau, et al, 2009;Yaseen et al, 2015). Several AI models, including the ANN (Mishra & Desai, 2006;Mishra et al, 2007;Morid et al, 2007), SVM (Ganguli & Reddy, 2014), and wavelet transformation (Maity et al, 2016;Özger et al, 2011), have been used to model complicated and nonlinear interactions between drought indicators and influencing factors for drought prediction.…”

Section: Artificial Intelligence Modelmentioning

confidence: 99%

Seasonal Drought Prediction: Advances, Challenges, and Future Prospects

Hao

Singh

Xia

2018

Reviews of Geophysics

361

232

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Drought prediction is of critical importance to early warning for drought managements. This review provides a synthesis of drought prediction based on statistical, dynamical, and hybrid methods. Statistical drought prediction is achieved by modeling the relationship between drought indices of interest and a suite of potential predictors, including large‐scale climate indices, local climate variables, and land initial conditions. Dynamical meteorological drought prediction relies on seasonal climate forecast from general circulation models (GCMs), which can be employed to drive hydrological models for agricultural and hydrological drought prediction with the predictability determined by both climate forcings and initial conditions. Challenges still exist in drought prediction at long lead time and under a changing environment resulting from natural and anthropogenic factors. Future research prospects to improve drought prediction include, but are not limited to, high‐quality data assimilation, improved model development with key processes related to drought occurrence, optimal ensemble forecast to select or weight ensembles, and hybrid drought prediction to merge statistical and dynamical forecasts.

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Section: Artificial Intelligence Modelmentioning

confidence: 99%

Seasonal Drought Prediction: Advances, Challenges, and Future Prospects

Hao

Singh

Xia

2018

Reviews of Geophysics

361

232

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“…Digital Elevation Models (DEMs) are one of the most important spatial input data sets in hydrological modelling (Bourdin, Fleming, & Stull, 2012;Wu, Li, & Huang, 2008). DEMs constitute a key spatial layer for estimating a watershed's channel networks, slope gradients, flow direction and accumulations, and several other controls of the water movements in landscapes (Moore, Grayson, & Ladson, 1991;Wechsler, 2007).…”

Section: Introductionmentioning

confidence: 99%

Impacts of DEM resolution, source, and resampling technique on SWAT-simulated streamflow

et al. 2015

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“…Results showed that statistical downscaling was better able to assess climate change effects on spring peak and summer low flows because of improved prediction of precipitation. Bourdin et al (2012) indicated that statistical downscaling approaches have been more popular because of Table 3). Adapted and updated from Bush et al (2014).…”

Section: Runoff and Streamflowmentioning

confidence: 96%

“…A hydrologic model inter-comparison might yield some useful insights, particularly considering the effects of model structural uncertainty which have led to differences in the representation of evaporation and snowmelt processes (Jiménez Cisneros et al 2014). Scenarios should include both climate and land changes (Bourdin et al 2012).…”

Section: Watersheds With Large Lakes And/or Glaciersmentioning

confidence: 99%

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Climate and water availability indicators in Canada: Challenges and a way forward. Part III – Future scenarios

Cohen

Koshida²,

Mortsch

2015

Canadian Water Resources Journal / Revue canadienne des ressour

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Following from Parts I and II of this series (this issue), some common approaches for developing and assessing future scenarios of water availability are reviewed, along with recent case studies of Canadian watersheds. The results of future changes in drought related to climate change are influenced by the choice of indicators. For the Standardized Precipitation Index (SPI), small changes in drought frequency and severity are projected over southern Canada, reflecting the influence of increases in future annual precipitation only. However, assessments using the Palmer Drought Severity Index (PDSI) reveal dramatic increases in the potential for future droughts since this indicator incorporates the combined influences of higher temperatures, soil moisture capacity and precipitation to estimate evapotranspiration. Regarding projected changes in runoff, watersheds in British Columbia tend to show increases in annual and winter runoff. Some watersheds show projected decreases in summer runoff. In the southern Prairies, most watersheds show projected decreases in annual and summer runoff. In Ontario and Quebec, results are mixed. Lake levels in the Great Lakes are projected to decline under most scenarios, but results differ between regional and global climate model-based scenarios due to differences in how lake evaporation is calculated. In New Brunswick, Labrador and northern Quebec, streamflow is projected to increase. Uncertainties in future projections emerge due to differences between climate scenario generating methods, and between hydrologic models used for the assessments. This paper concludes with some thoughts on addressing important research questions related to future scenarios of water availability in Canada. For scenario-based assessments, hydrologic model inter-comparisons might yield some useful insights into uncertainties in model structure that affect evaporation, evapotranspiration and snowmelt calculations. Scenarios developed for assessments should include both future climate and projected land use/cover changes and, where necessary, integration of potential reduction in glacier volume. Finally, as scenarios from regional climate models become more readily available, there may be more opportunity to explore how runoff projections could be applied to basin-scale routing models. À la suite des parties I et II de cette série, des méthodes d'élaboration et d'évaluation de futurs scénarios concernant la disponibilité de l'eau seront examinées, ainsi que des études de cas portant sur les bassins versants du Canada. Les résultats des futurs changements des conditions de sécheresse liés aux changements climatiques sont influencés par le choix des indicateurs. Pour l'indice de précipitation standardisé (SPI), des changements mineurs liés à la fréquence et la gravité des sécheresses sont prévus dans le sud du Canada, indiquant l'influence de l'augmentation des futures précipitations annuelles seulement. Cependant, les évaluations utilisant l'indice de sévérité de sécheresse de Palmer (ISSP) révèlent une aug...

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Streamflow Modelling: A Primer on Applications, Approaches and Challenges

Cited by 79 publications

References 253 publications

Seasonal Drought Prediction: Advances, Challenges, and Future Prospects

Seasonal Drought Prediction: Advances, Challenges, and Future Prospects

Impacts of DEM resolution, source, and resampling technique on SWAT-simulated streamflow

Climate and water availability indicators in Canada: Challenges and a way forward. Part III – Future scenarios

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