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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
61

Previsão de cheias por conjunto em curto prazo

Meller, Adalberto January 2012 (has links)
A previsão e emissão de alertas antecipados constituem um dos principais elementos na prevenção dos impactos ocasionados por eventos de cheias. Uma das formas utilizadas para se obter uma ampliação do horizonte de previsão é através do uso da modelagem chuva-vazão associada à previsão de precipitação, tipicamente derivada de modelos meteorológicos. A precipitação, no entanto, é uma das variáveis que impõe maior dificuldade na previsão meteorológica, sendo considerada uma das principais fontes de incerteza nos resultados da previsão de cheias. A previsão por conjunto é uma técnica originalmente desenvolvida nas ciências atmosféricas e procura explorar as incertezas associadas às condições iniciais e/ou deficiências na estrutura dos modelos meteorológicos com intuito de melhorar sua previsibilidade. A partir de diferentes modelos meteorológicos ou de diferentes condições iniciais de um único modelo, são gerados um conjunto de previsões que representam possíveis trajetórias dos processos atmosféricos ao longo do horizonte de previsão. Pesquisas recentes, principalmente na Europa e Estados Unidos, têm mostrado resultados promissores do acoplamento de previsões meteorológicas por conjunto à modelos hidrológicos para realizar previsões de cheia. Essa pesquisa trata da avaliação do benefício da previsão de cheias por conjunto em curto prazo, em uma bacia de médio porte, utilizando dados e de ferramentas para previsão de vazões disponíveis em modo operacional no Brasil. Como estudo de caso foi utilizada a bacia do Rio Paraopeba (12.150km²), de clima tipicamente tropical, localizada na região sudeste do Brasil. A metodologia proposta para geração das previsões hidrológicas utilizou o modelo hidrológico MGB-IPH alimentado por um conjunto previsões de precipitação de diferentes modelos, com diferentes condições iniciais e parametrizações, dando origem a distintos cenários de previsão de vazões. Como parâmetro de referência na avaliação do desempenho das previsões por conjunto foi utilizada uma previsão hidrológica determinística única, baseada em uma previsão de precipitação obtida da combinação ótima de saídas de diversos modelos meteorológicos. As previsões foram realizadas retrospectivamente no período entre ago/2008 e mai/2011, sendo analisadas durante o período chuvoso dos anos hidrológicos (out-abr). Os resultados das previsões de cheia por conjunto foram avaliados através de uma representação determinística, considerando a média dos membros do conjunto, assim como através de uma representação probabilística, considerando todos os membros, através de medidas de desempenho específicas para esse fim. Na avaliação determinística, a média do conjunto hidrológico apresentou resultados similares aos obtido com a previsão determinística de referência, embora tenha apresentado benefício significativo em relação à maior parte dos membros do conjunto. A avaliação das previsões de cheia por conjunto, por sua vez, mostrou a existência de uma superestimativa e de um subespalhamento dos membros em relação às observações, sobretudo nos primeiros intervalos de tempo da previsão. Na comparação dos resultados das previsões de eventos do tipo dicótomos, que consideram a superação ou não de vazões limites de alerta, o 9º decil das previsões por conjunto mostrou superioridade em relação à previsão determinística de referência e mesmo a média do conjunto, sendo possível obter, na maior parte dos casos analisados, um aumento significativo na proporção de eventos corretamente previstos mantendo as taxas de alarmes falsos em níveis reduzidos. Esse benefício foi, de modo geral, maior para maiores antecedências e vazões limites, situações mais importantes num contexto de prevenção de cheias. Os resultados mostraram ainda que, em média, uma diminuição do número de membros do conjunto diminui seu desempenho nas previsões. / The forecasting and issuing of early warnings represent a key element to prevent the impacts of flood events. An alternative to extend forecasting horizon is the use of rainfall-runoff modeling coupled with precipitation forecasts derived from numerical weather prediction (NWP) models. However, NWP models have difficulty to accurately predict precipitation due to the extremely sensitivity of the initial conditions. Therefore, this variable represents one of the major sources of uncertainties in flood forecasting. A probabilistic or ensemble forecasting approach was originally developed in the atmospheric sciences and then applied to other research areas. This procedure explores the uncertainties related to initial conditions and deficiencies in the structure of NWP models intending to improve its predictability. Using different NWP models or different initial conditions of a single model, an ensemble forecast showing possible trajectories of atmospheric processes over the forecast horizon are produced. Recent studies developed in Europe and the United States have shown promising results in flood forecasting using hydrological models fed by NWP ensemble outputs. The present research assess the performance of short term ensemble flood forecasting in a medium size tropical basin, based on data and streamflow forecasting tools available in operational mode in Brazil. The Paraopeba River basin (12,150 km²), located in the upper portion of the São Francisco River basin, in Southeastern Brazil, was selected as a case study. The proposed methodology used the MGB-IPH hydrological coupled to an ensemble of precipitation forecasts generated by several models with different initial conditions and parameterizations. The results are several scenarios of streamflow forecasts. A single deterministic streamflow forecast, based on a quantitative precipitation forecast derived from the optimal combination of several outputs of NWP models, was used as a reference to assess the performance of the streamflow ensemble forecasts. The streamflow forecasts were performed between aug/2008 and may/2011 and were analyzed during the rainy seasons (austral summer). The results from the ensemble flood forecasting were assessed by deterministic and probabilistic performance measures, with the ensemble mean being used by the former, and specific assessment measure by the later. Based on the deterministic assessment, the ensemble mean showed similar results to those obtained by the deterministic reference forecast, although showing better performance over most of the ensemble members. Based on the probabilistic performance measures, however, results showed the existence of an ensemble overforecasting and underspread of the members in regard to observed values, especially during the first lead times. The results for predictions of dichotomous events, which mean exceeding or not flood warning thresholds, showed that the 9th decile of the ensemble over performed the deterministic forecast and even the ensemble mean. In most cases, it was observed an increase in the proportion of correctly forecasted events while keeping false alarm rates at low levels. This benefit was generally higher for higher flow thresholds and for longer lead times, which are the most important situations for flood mitigation. The results show, also, that, in average, a reduction in the number of ensemble members decreases the performance of ensemble flood forecasts.
62

Hydro-climatic forecasting using sea surface temperatures

Chen, Chia-Jeng 20 June 2012 (has links)
A key determinant of atmospheric circulation patterns and regional climatic conditions is sea surface temperature (SST). This has been the motivation for the development of various teleconnection methods aiming to forecast hydro-climatic variables. Among such methods are linear projections based on teleconnection gross indices (such as the ENSO, IOD, and NAO) or leading empirical orthogonal functions (EOFs). However, these methods deteriorate drastically if the predefined indices or EOFs cannot account for climatic variability in the region of interest. This study introduces a new hydro-climatic forecasting method that identifies SST predictors in the form of dipole structures. An SST dipole that mimics major teleconnection patterns is defined as a function of average SST anomalies over two oceanic areas of appropriate sizes and geographic locations. The screening process of SST-dipole predictors is based on an optimization algorithm that sifts through all possible dipole configurations (with progressively refined data resolutions) and identifies dipoles with the strongest teleconnection to the external hydro-climatic series. The strength of the teleconnection is measured by the Gerrity Skill Score. The significant dipoles are cross-validated and used to generate ensemble hydro-climatic forecasts. The dipole teleconnection method is applied to the forecasting of seasonal precipitation over the southeastern US and East Africa, and the forecasting of streamflow-related variables in the Yangtze and Congo Rivers. These studies show that the new method is indeed able to identify dipoles related to well-known patterns (e.g., ENSO and IOD) as well as to quantify more prominent predictor-predictand relationships at different lead times. Furthermore, the dipole method compares favorably with existing statistical forecasting schemes. An operational forecasting framework to support better water resources management through coupling with detailed hydrologic and water resources models is also demonstrated.
63

Modelling the sporadic behaviour of rainfall in the Limpopo Province, South Africa

Molautsi, Selokela Victoria January 2021 (has links)
Thesis (M. Sc. (Statistics)) -- University of Limpopo, 2021 / The effects of ozone depletion on climate change has, in recent years, become a reality, impacting on changes in rainfall patterns and severity of extreme floods or extreme droughts. The majority of people across the entire African continent live in semi-arid and drought-prone areas. Extreme droughts are prevalent in Somalia and eastern Africa, while life-threatening floods are common in Mozambique and some parts of other SADC (Southern African Development Community) countries. Research has cautioned that climate change in South Africa might lead to increased temperatures and reduced amounts of rainfall, thereby altering their timing and putting more pressure on the country’s scarce water resources, with implications for agriculture, employment and food security. The average annual rainfall for South Africa is about 464mm, falling far below the average annual global rainfall of 860mm. The Limpopo Province, which is one of the nine provinces in South Africa, and of interest to this study, is predominantly agrarian, basically relying on availability of water, with rainfall being the major source for water supply. It is, therefore, pertinent that the rainfall pattern in the province be monitored effectively to ascertain the rainy period for farming activities and other uses. Modelling and forecasting rainfall have been studied for a long time worldwide. However, from time to time, researchers are always looking for new models that can predict rainfall more accurately in the midst of climate change and capture the underlying dynamics such as seasonality and the trend, attributed to rainfall. This study employed Exponetial Smoothing (ETS) State Space and Seasonal Autoregressive Integrated Moving Average (SARIMA) models and compared their forecasting ability using root mean square error (RMSE). Both models were used to capture the sporadic behaviour of rainfall. These two models have been widely applied to climatic data by many scholars and adjudged to perform creditably well. In an attempt to find a suitable prediction model for monthly rainfall patterns in Limpopo Province, data ranging from January 1900 to December 2015, for seven weather stations: Macuville Agriculture, Mara Agriculture, Marnits, Groendraal, Letaba, Pietersburg Hospital and Nebo, were analysed. The results showed that the two models were adequate in predicting rainfall patterns for the different stations in the Limpopo Province. / National Research Foundation (NRF)
64

Climate Change Assessment in Columbia River Basin (CRB) Using Copula Based on Coupling of Temperature and Precipitation

Qin, Yueyue 29 May 2015 (has links)
The multi downscaled-scenario products allow us to better assess the uncertainty of the variations of precipitation and temperature in the current and future periods. Joint Probability distribution functions (PDFs), of both the climatic variables, might help better understand the interdependence of the two, and thus in-turn help in accessing the future with confidence. In the present study, we have used multi-modelled statistically downscaled ensemble of precipitation and temperature variables. The dataset used is multi-model ensemble of 10 Global Climate Models (GCMs) downscaled product from CMIP5 daily dataset, using the Bias Correction and Spatial Downscaling (BCSD) technique, generated at Portland State University. The multi-model ensemble PDFs of both precipitation and temperature is evaluated for summer (dry) and winter (wet) periods for 10 sub-basins across Columbia River Basin (CRB). Eventually, Copula is applied to establish the joint distribution of two variables on multi-model ensemble data. Results have indicated that the probabilistic distribution helps remove the limitations on marginal distributions of variables in question and helps in better prediction. The joint distribution is then used to estimate the change in trends of said variables in future, along with estimation of the probabilities of the given change. The joint distribution trends are varied, but certainly positive, for summer and winter time scales based on sub-basins. Dry season, generally, is indicating towards higher positive changes in precipitation than temperature (as compared to historical) across sub-basins with wet season inferring otherwise. Probabilities of changes in future, as estimated by the joint precipitation and temperature, also indicates varied degree and forms during dry season whereas the wet season is rather constant across all the sub-basins.
65

Rainfall derivatives for Hong Kong Disneyland.

January 2003 (has links)
by Ng Wing-Sze Cecilia. / Thesis (M.B.A.)--Chinese University of Hong Kong, 2003. / Includes bibliographical references (leaves 92-93). / ABSTRACT --- p.ii / TABLE OF CONTENT --- p.iii / CHAPTER / Chapter 1. --- COMPANY PROFILE --- p.1 / The Walt Disney Parks --- p.1 / Hong Kong Disneyland --- p.1 / Location --- p.1 / Park Developer & Operator --- p.2 / Financing --- p.2 / Infrastructure --- p.3 / Schedule of Operation --- p.4 / Chapter 2. --- HONG KONG DISNEYLAND BUSINESS MODEL --- p.6 / Revenue Model --- p.7 / Customer Base --- p.7 / Pricing Strategy --- p.8 / Financial Performance Variable --- p.9 / Risk Management Program --- p.10 / The Walt Disney Company Risk Management --- p.10 / HKDL Risk Management --- p.13 / Risk Management on Book Record --- p.13 / Chapter 3. --- PRECIPITATION RISK EXPOSURE --- p.15 / Introduction to Precipitation --- p.15 / Distinguish between Weather and Climate --- p.16 / Rainfall Risk Exposure --- p.16 / Precipitation in Hong Kong --- p.17 / Overview --- p.17 / Rainstorm Warning System --- p.18 / Practices on Rainy Days --- p.20 / Theme Park Industry --- p.20 / The Ocean Park --- p.21 / Rainfall Risk Mitigation --- p.21 / Chapter 4. --- WEATHER DERIVATIVES --- p.24 / Evolution --- p.24 / The Birth of Weather Derivatives --- p.24 / Weather Risk Management Association --- p.24 / Year 1999 --- p.25 / Year 2000 --- p.25 / Year 2001 --- p.26 / Year 2002 --- p.26 / Precipitation Derivatives --- p.27 / Market & Market Players --- p.28 / Types of Product --- p.30 / Index Derivatives --- p.30 / Event-Basis Derivatives --- p.32 / Chapter 5. --- Hedging Against Rainfall Risk with Weather Derivatives --- p.33 / Formation of Hedging Strategy --- p.34 / Hedging Objectives --- p.34 / Hedging Target --- p.35 / Dimension of Precipitation Impacts --- p.35 / Normal Revenue without Rainfall Risk --- p.40 / Revenue Forecasting for Year 1 --- p.41 / Specifications on the Contracts --- p.46 / Chapter 6. --- General Recommendations to HKDL for hedging with all kinds of Rainfall Derivatives --- p.49 / Choice of Market and Counter Parties --- p.49 / Index Model Design --- p.50 / Dimensions of Variables & Time Scale --- p.50 / Accumulated Rainfall Index --- p.51 / Methodologies of Rainfall Measurements --- p.54 / Location of Rainfall Measuring Stations --- p.54 / Measuring Instrument --- p.56 / Historical Data Consistency --- p.58 / Data Availability and Reliability --- p.59 / Choice of Strike Level --- p.59 / Tick Size and Maximum Payments --- p.62 / Pricing Approach --- p.63 / Chapter 7. --- Example of Rainfall Derivatives --- p.66 / Black/Red Rainstorm Signal Call --- p.66 / Specifications --- p.66 / Revenue model under Different Scenario --- p.68 / Chapter 8. --- Portfolio Management --- p.70 / Risk Management Information System --- p.70 / Issues on Book Keeping --- p.71 / Chapter 9. --- CONCULSION --- p.72
66

Water resources availability in the Caledon River basin : past, present and future

Mohobane, Thabiso January 2015 (has links)
The Caledon River Basin is located on one of the most water-scarce region on the African continent. The water resources of the Caledon River Basin play a pivotal role in socio-economic activities in both Lesotho and South Africa but the basin experiences recurrent severe droughts and frequent water shortages. The Caledon River is mostly used for commercial and subsistence agriculture, industrial and domestic supply. The resources are also important beyond the basin’s boundaries as the water is transferred to the nearby Modder River. The Caledon River is also a significant tributary to the Orange-Senqu Basin, which is shared by five southern African countries. However, the water resources in the basin are under continuous threat as a result of rapidly growing population, economic growth as well as changing climate, amongst others. It is therefore important that the hydrological regime and water resources of the basin are thoroughly evaluated and assessed so that they can be sustainably managed and utilised for maximum economic benefits. Climate change has been identified by the international community as one of the most prominent threats to peace, food security and livelihood and southern Africa as among the most vulnerable regions of the world. Water resources are perceived as a natural resource which will be affected the most by the changing climate conditions. Global warming is expected to bring more severe, prolonged droughts and exacerbate water shortages in this region. The current study is mainly focused on investigating the impacts of climate change on the water resources of the Caledon River Basin. The main objectives of the current study included assessing the past and current hydrological characteristics of the Caledon River Basin under current state of the physical environment, observed climate conditions and estimated water use; detecting any changes in the future rainfall and evaporative demands relative to present conditions and evaluating the impacts of climate on the basin’s hydrological regime and water resources availability for the future climate scenario, 2046-2065. To achieve these objectives the study used observed hydrological, meteorological data sets and the basin’s physical characteristics to establish parameters of the Pitman and WEAP hydrological models. Hydrological modelling is an integral part of hydrological investigations and evaluations. The various sources of uncertainties in the outputs of the climate and hydrological models were identified and quantified, as an integral part of the whole exercise. The 2-step approach of the uncertainty version of the model was used to estimate a range of parameters yielding behavioural natural flow ensembles. This approach uses the regional and local hydrological signals to constrain the model parameter ranges. The estimated parameters were also employed to guide the calibration process of the Water Evaluation And Planning (WEAP) model. The two models incorporated the estimated water uses within the basin to establish the present day flow simulations and they were found to sufficiently simulate the present day flows, as compared to the observed flows. There is an indication therefore, that WEAP can be successfully applied in other regions for hydrological investigations. Possible changes in future climate regime of the basin were evaluated by analysing downscaled temperature and rainfall outputs from a set of 9 climate models. The predictions are based on the A2 greenhouse gases emission scenario which assumes a continuous increase in emission rates. While the climate models agree that temperature, and hence, evapotranspiration will increase in the future, they demonstrate significant disagreement on whether rainfall will decrease or increase and by how much. The disagreement of the GCMs on projected future rainfall constitutes a major uncertainty in the prediction of water resources availability of the basin. This is to the extent that according to 7 out of 9 climate models used, the stream flow in four sub-basins (D21E, D22B, D23D and D23F) in the Caledon River Basin is projected to decrease below the present day flows, while two models (IPSL and MIUB) consistently project enhanced water resource availability in the basin in the future. The differences in the GCM projections highlight the margin of uncertainty involved predicting the future status of water resources in the basin. Such uncertainty should not be ignored and these results can be useful in aiding decision-makers to develop policies that are robust and that encompass all possibilities. In an attempt to reduce the known uncertainties, the study recommends upgrading of the hydrological monitoring network within the Caledon River Basin to facilitate improved hydrological evaluation and management. It also suggests the use of updated climate change data from the newest generation climate models, as well as integrating the findings of the current research into water resources decision making process.
67

Climate Change Impacts on Precipitation Extremes over the Columbia River Basin Based on Downscaled CMIP5 Climate Scenarios

Dars, Ghulam Hussain 29 May 2013 (has links)
Hydro-climate extreme analysis helps understanding the process of spatio-temporal variation of extreme events due to climate change, and it is an important aspect in designing hydrological structures, forecasting floods and an effective decision making in the field of water resources design and management. The study evaluates extreme precipitation events over the Columbia River Basin (CRB), the fourth largest basin in the U.S., by simulating four CMIP5 global climate models (GCMs) for the historical period (1970-1999) and future period (2041-2070) under RCP85 GHG scenario. We estimated the intensity of extreme and average precipitation for both winter (DJF) and summer (JJA) seasons by using the GEV distribution and multi-model ensemble average over the domain of the Columbia River Basin. The four CMIP5 models performed very well at simulating precipitation extremes in the winter season. The CMIP5 climate models showed heterogeneous spatial pattern of summer extreme precipitation over the CRB for the future period. It was noticed that multi-model ensemble mean outperformed compared to the individual performance of climate models for both seasons. We have found that the multi-model ensemble shows a consistent and significant increase in the extreme precipitation events in the west of the Cascades Range, Coastal Ranges of Oregon and Washington State, the Canadian portion of the basin and over the Rocky Mountains. However, the mean precipitation is projected to decrease in both winter and summer seasons in the future period. The Columbia River is dominated by the glacial snowmelt, so the increase in the intensity of extreme precipitation and decrease in mean precipitation in the future period, as simulated by four CMIP5 models, is expected to aggravate the earlier snowmelt and contribute to the flooding in the low lying areas especially in the west of the Cascades Range. In addition, the climate change shift could have serious implications on transboundary water issues in between the United States and Canada. Therefore, adaptation strategies should be devised to cope the possible adverse effects of the changing the future climate so that it could have minimal influence on hydrology, agriculture, aquatic species, hydro-power generation, human health and other water related infrastructure.
68

Use of large-scale atmospheric flow patterns to improve forecasting of extreme precipitation in the Mediterranean region for longer-range forecasts

Mastrantonas, Nikolaos 31 May 2023 (has links)
The Mediterranean region frequently experiences extreme precipitation events (EPEs) with devastating consequences for affected societies, economies, and environment. Thus, it is crucial to better understand their characteristics and drivers and improve their predictions at longer lead times. This work provides new insights about the spatiotemporal dependencies of EPEs in the region. It, moreover, implements Empirical Orthogonal Function analysis and subsequent non-hierarchical Kmeans clustering for generating nine distinct weather patterns over the domain, referred to as “Mediterranean patterns”. These patterns are significantly associated with EPEs across the region, and in fact, can be used to extend the forecasting horizon of EPEs. This is demonstrated considering modelled data for all the domain, but also using observational data for Calabria, southern Italy, an area of complex topography that increases the challenges of weather prediction. The results suggest preferential techniques for improving EPEs predictions for short, medium, and extended range forecasts, supporting thus the mitigation of their negative impacts.
69

Probabilistic Ensemble-based Streamflow Forecasting Framework

Darbandsari, Pedram January 2021 (has links)
Streamflow forecasting is a fundamental component of various water resources management systems, ranging from flood control and mitigation to long-term planning of irrigation and hydropower systems. In the context of floods, a probabilistic forecasting system is required for proper and effective decision-making. Therefore, the primary goal of this research is the development of an advanced ensemble-based streamflow forecasting framework to better quantify the predictive uncertainty and generate enhanced probabilistic forecasts. This research started by comprehensively evaluating the performances of various lumped conceptual models in data-poor watersheds and comparing various Bayesian Model Averaging (BMA) modifications for probabilistic streamflow simulation. Then, using the concept of BMA, two novel probabilistic post-processing approaches were developed to enhance streamflow forecasting performance. The combination of the entropy theory and the BMA method leads to an entropy-based Bayesian Model Averaging (En-BMA) approach for enhanced probabilistic streamflow and precipitation forecasting. Also, the integration of the Hydrologic Uncertainty Processor (HUP) and the BMA methods is proposed for probabilistic post-processing of multi-model streamflow forecasts. Results indicated that the MACHBV and GR4J models are highly competent in simulating hydrological processes within data-scarce watersheds, however, the presence of the lower skill hydrologic models is still beneficial for ensemble-based streamflow forecasting. The comprehensive verification of the BMA approach in terms of streamflow predictions has identified the merits of implementing some of the previously recommended modifications and showed the importance of possessing a mutually exclusive and collectively exhaustive ensemble. By targeting the remaining limitation of the BMA approach, the proposed En-BMA method can improve probabilistic streamflow forecasting, especially under high flow conditions. Also, the proposed HUP-BMA approach has taken advantage of both HUP and BMA methods to better quantify the hydrologic uncertainty. Moreover, the applicability of the modified En-BMA as a more robust post-processing approach for precipitation forecasting, compared to BMA, has been demonstrated. / Thesis / Doctor of Philosophy (PhD) / Possessing a reliable streamflow forecasting framework is of special importance in various fields of operational water resources management, non-structural flood mitigation in particular. Accurate and reliable streamflow forecasts lead to the best possible in-advanced flood control decisions which can significantly reduce its consequent loss of lives and properties. The main objective of this research is to develop an enhanced ensemble-based probabilistic streamflow forecasting approach through proper quantification of predictive uncertainty using an ensemble of streamflow forecasts. The key contributions are: (1) implementing multiple diverse forecasts with full coverage of future possibilities in the Bayesian ensemble-based forecasting method to produce more accurate and reliable forecasts; and (2) developing an ensemble-based Bayesian post-processing approach to enhance the hydrologic uncertainty quantification by taking the advantages of multiple forecasts and initial flow observation. The findings of this study are expected to benefit streamflow forecasting, flood control and mitigation, and water resources management and planning.
70

Medium-range probabilistic river streamflow predictions

Roulin, Emmannuel 30 June 2014 (has links)
River streamflow forecasting is traditionally based on real-time measurements of rainfall over catchments and discharge at the outlet and upstream. These data are processed in mathematical models of varying complexity and allow to obtain accurate predictions for short times. In order to extend the forecast horizon to a few days - to be able to issue early warning - it is necessary to take into account the weather forecasts. However, the latter display the property of sensitivity to initial conditions, and for appropriate risk management, forecasts should therefore be considered in probabilistic terms. Currently, ensemble predictions are made using a numerical weather prediction model with perturbed initial conditions and allow to assess uncertainty. <p><p>The research began by analyzing the meteorological predictions at the medium-range (up to 10-15 days) and their use in hydrological forecasting. Precipitation from the ensemble prediction system of the European Centre for Medium-Range Weather Forecasts (ECMWF) were used. A semi-distributed hydrological model was used to transform these precipitation forecasts into ensemble streamflow predictions. The performance of these forecasts was analyzed in probabilistic terms. A simple decision model also allowed to compare the relative economic value of hydrological ensemble predictions and some deterministic alternatives. <p><p>Numerical weather prediction models are imperfect. The ensemble forecasts are therefore affected by errors implying the presence of biases and the unreliability of probabilities derived from the ensembles. By comparing the results of these predictions to the corresponding observed data, a statistical model for the correction of forecasts, known as post-processing, has been adapted and shown to improve the performance of probabilistic forecasts of precipitation. This approach is based on retrospective forecasts made by the ECMWF for the past twenty years, providing a sufficient statistical sample. <p><p>Besides the errors related to meteorological forcing, hydrological forecasts also display errors related to initial conditions and to modeling errors (errors in the structure of the hydrological model and in the parameter values). The last stage of the research was therefore to investigate, using simple models, the impact of these different sources of error on the quality of hydrological predictions and to explore the possibility of using hydrological reforecasts for post-processing, themselves based on retrospective precipitation forecasts. <p>/<p>La prévision des débits des rivières se fait traditionnellement sur la base de mesures en temps réel des précipitations sur les bassins-versant et des débits à l'exutoire et en amont. Ces données sont traitées dans des modèles mathématiques de complexité variée et permettent d'obtenir des prévisions précises pour des temps courts. Pour prolonger l'horizon de prévision à quelques jours – afin d'être en mesure d'émettre des alertes précoces – il est nécessaire de prendre en compte les prévisions météorologiques. Cependant celles-ci présentent par nature une dynamique sensible aux erreurs sur les conditions initiales et, par conséquent, pour une gestion appropriée des risques, il faut considérer les prévisions en termes probabilistes. Actuellement, les prévisions d'ensemble sont effectuées à l'aide d'un modèle numérique de prévision du temps avec des conditions initiales perturbées et permettent d'évaluer l'incertitude.<p><p>La recherche a commencé par l'analyse des prévisions météorologiques à moyen-terme (10-15 jours) et leur utilisation pour des prévisions hydrologiques. Les précipitations issues du système de prévisions d'ensemble du Centre Européen pour les Prévisions Météorologiques à Moyen-Terme ont été utilisées. Un modèle hydrologique semi-distribué a permis de traduire ces prévisions de précipitations en prévisions d'ensemble de débits. Les performances de ces prévisions ont été analysées en termes probabilistes. Un modèle de décision simple a également permis de comparer la valeur économique relative des prévisions hydrologiques d'ensemble et d'alternatives déterministes.<p><p>Les modèles numériques de prévision du temps sont imparfaits. Les prévisions d'ensemble sont donc entachées d'erreurs impliquant la présence de biais et un manque de fiabilité des probabilités déduites des ensembles. En comparant les résultats de ces prévisions aux données observées correspondantes, un modèle statistique pour la correction des prévisions, connue sous le nom de post-processing, a été adapté et a permis d'améliorer les performances des prévisions probabilistes des précipitations. Cette approche se base sur des prévisions rétrospectives effectuées par le Centre Européen sur les vingt dernières années, fournissant un échantillon statistique suffisant.<p><p>A côté des erreurs liées au forçage météorologique, les prévisions hydrologiques sont également entachées d'erreurs liées aux conditions initiales et aux erreurs de modélisation (structure du modèle hydrologique et valeur des paramètres). La dernière étape de la recherche a donc consisté à étudier, à l'aide de modèles simples, l'impact de ces différentes sources d'erreur sur la qualité des prévisions hydrologiques et à explorer la possibilité d'utiliser des prévisions hydrologiques rétrospectives pour le post-processing, elles-même basées sur les prévisions rétrospectives des précipitations. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

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