32 results on '"Nikolopoulos, Efthymios I."'
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2. Evaluation of Global Water Resources Reanalysis Products in the Upper Blue Nile River Basin
- Author
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Koukoula, Marika, Nikolopoulos, Efthymios I., Dokou, Zoi, and Anagnostou, Emmanouil N.
- Published
- 2020
3. How deregulation, drought and increasing fire impact Amazonian biodiversity
- Author
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Feng, Xiao, Merow, Cory, Liu, Zhihua, Park, Daniel S., Roehrdanz, Patrick R., Maitner, Brian, Newman, Erica A., Boyle, Brad L., Lien, Aaron, Burger, Joseph R., Pires, Mathias M., Brando, Paulo M., Bush, Mark B., McMichael, Crystal N. H., Neves, Danilo M., Nikolopoulos, Efthymios I., Saleska, Scott R., Hannah, Lee, Breshears, David D., Evans, Tom P., Soto, José R., Ernst, Kacey C., and Enquist, Brian J.
- Published
- 2021
- Full Text
- View/download PDF
4. Machine Learning–Based Blending of Satellite and Reanalysis Precipitation Datasets : A Multiregional Tropical Complex Terrain Evaluation
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Bhuiyan, Md. Abul Ehsan, Nikolopoulos, Efthymios I., and Anagnostou, Emmanouil N.
- Published
- 2019
5. A Numerical Sensitivity Analysis of Soil Moisture Feedback on Convective Precipitation
- Author
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Koukoula, Marika, Nikolopoulos, Efthymios I., Kushta, Jonilda, Bartsotas, Nikolaos S., Kallos, George, and Anagnostou, Emmanouil N.
- Published
- 2019
6. Moving toward Subkilometer Modeling Grid Spacings : Impacts on Atmospheric and Hydrological Simulations of Extreme Flash Flood–Inducing Storms
- Author
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Bartsotas, Nikolaos S., Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., Solomos, Stavros, and Kallos, George
- Published
- 2017
7. First Evaluation of the Day-1 IMERG over the Upper Blue Nile Basin
- Author
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Sahlu, Dejene, Nikolopoulos, Efthymios I., Moges, Semu A., Anagnostou, Emmanouil N., and Hailu, Dereje
- Published
- 2016
8. Spatial estimation of debris flows-triggering rainfall and its dependence on rainfall return period
- Author
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Destro, Elisa, Marra, Francesco, Nikolopoulos, Efthymios I., Zoccatelli, Davide, Creutin, Jean Dominique, and Borga, Marco
- Published
- 2017
- Full Text
- View/download PDF
9. Multiregional Satellite Precipitation Products Evaluation over Complex Terrain
- Author
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Derin, Yagmur, Anagnostou, Emmanouil, Berne, Alexis, Borga, Marco, Boudevillain, Brice, Buytaert, Wouter, Chang, Che-Hao, Delrieu, Guy, Hong, Yang, Hsu, Yung Chia, Lavado-Casimiro, Waldo, Manz, Bastian, Moges, Semu, Nikolopoulos, Efthymios I., Sahlu, Dejene, Salerno, Franco, Rodríguez-Sánchez, Juan-Pablo, Vergara, Humberto J., and Yilmaz, Koray K.
- Published
- 2016
10. Evaluating Satellite Precipitation Error Propagation in Runoff Simulations of Mountainous Basins
- Author
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Mei, Yiwen, Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., and Borga, Marco
- Published
- 2016
11. Predictive Understanding of Socioeconomic Flood Impact in Data-Scarce Regions Based on Channel Properties and Storm Characteristics: Application in High Mountain Asia (HMA).
- Author
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Khanam, Mariam, Sofia, Giulia, Rodriguez, Wilmalis, Nikolopoulos, Efthymios I., Binghao Lu, Dongjin Song, and Anagnostou, Emmanouil N.
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FLOOD risk ,EXTREME weather ,WEATHER ,RAINFALL ,FLOODS ,DIGITAL elevation models - Abstract
The exposure of High Mountain Asia (HMA) to disaster risks is heightened by extreme weather conditions and the impacts of climate change. Obtaining knowledge about the long-term response of the landscape to hydroclimatic variations in HMA is paramount, as millions of people are affected by these changes every year. During monsoons, substantial human suffering, and damage to crops and infrastructure in populated communities result from the flooding and debris flow caused by the increase in precipitation extremes each year. Although a few initiatives have undertaken the estimation of flood risk locally, the use of traditional techniques in ungauged basins is, unfortunately, not always possible because of the lack of extensive data required. To address this problem, we present in this study a geomorphologically guided machine learning (ML) approach for mapping flood impacts across HMA. We defined socioeconomic flood impact using the Lifeyears Index (LYI), a systematic index that measures the economic cost and loss of life caused by flooding. This index quantifies the importance of the destruction to infrastructure, capital, and housing in an overall assessment. We trained the proposed model with over 6000 flood events, from 1980 to 2020, and their computed five-year and ten-year LYIs. We used as predictors, (1) the five-year rainfall concentrations (which correlate the magnitude of precipitation events with the time of occurrence) of events retrieved from ERA5 daily data; (2) a geomorphic classifier (flood geomorphic potential) based on hydraulic scaling functions automatically derived from an 8 and 30-meter digital elevation model (DEM) for the region and (3) population. This model proved capable of identifying the hotspots of flood susceptibility on a national scale and showing its variability from 1980 to 2022. The study also highlights the severity of the impacts of hydroclimatic extremes in the entire HMA region. The framework is generic and can be used to derive a wide variety of flood vulnerability and subsequent risk maps in data-scarce regions. [ABSTRACT FROM AUTHOR]
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- 2023
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12. Reply to “Comments on ‘Error Analysis of Satellite Precipitation Products in Mountainous Basins’”
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Mei, Yiwen, Anagnostou, Emmanouil N., Nikolopoulos, Efthymios I., and Borga, Marco
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- 2015
13. Error Analysis of Satellite Precipitation Products in Mountainous Basins
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Mei, Yiwen, Anagnostou, Emmanouil N., Nikolopoulos, Efthymios I., and Borga, Marco
- Published
- 2014
14. Toward an improved estimation of flood frequency statistics from simulated flows.
- Author
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Hu, Lanxin, Nikolopoulos, Efthymios I., Marra, Francesco, and Anagnostou, Emmanouil N.
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FLOODS ,EXTREME value theory ,HYDROLOGIC models ,STREAMFLOW ,TIME series analysis ,COASTS - Abstract
The estimation of extreme flood frequency for ungauged or poorly gauged catchments is a longstanding problem of great practical importance. Simulated streamflow derived from distributed hydrological models can be used to address this issue, but their representation of extreme flood peaks is often prone to large biases. This study evaluates the potential of a nonasymptotic statistical approach able to consider all the independent flood peaks instead of extremes only, the Simplified Metastatistical Extreme Value (SMEV), for the estimation of extreme flood frequency from time series of simulated streamflow. We examined 28 years of simulated daily streamflow across the contiguous United States and compared SMEV to traditional statistical models based on annual maxima. Our results suggest that when its assumptions are met SMEV can moderate the impact of hydrological model biases in the quantification of extreme flood frequency. SMEV exhibits a lower relative difference between quantiles derived from observations and simulations for all return periods and forcing dataset. Quantiles estimated from simulated streamflow time series (28‐year records) using SMEV are usually in better agreement with the estimates based on 70‐year‐long observations. Geographical variations in the results of SMEV are noticed, with a better performance of SMEV in the east and west coasts (California, New England, and Mid‐Atlantic) and in the southwestern regions (Texas‐Gulf). These results indicate that the potential of SMEV for flood frequency analyses in ungauged and poorly gauged basins deserves further investigations. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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15. Exploring the Future of Rainfall Extremes Over CONUS: The Effects of High Emission Climate Change Trajectories on the Intensity and Frequency of Rare Precipitation Events.
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Emmanouil, Stergios, Langousis, Andreas, Nikolopoulos, Efthymios I., and Anagnostou, Emmanouil N.
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RAINFALL ,CLIMATE change ,CLIMATE extremes ,CONUS ,ATMOSPHERIC models ,RAINSTORMS - Abstract
The impacts of climate change on extreme rainfall characteristics at fine spatiotemporal scales are governed by substantial uncertainty, primarily due to the systematic error components inherited from conventional numerical prediction systems, and/or the intrinsic assumptions of the selected modeling schemes. Here, we attempt to robustly evaluate the effects of future climate scenarios on intensity‐duration‐frequency (IDF) curves over the entire Contiguous United States, while accounting for the nonstationary nature of the rainfall process across adequately fine spatiotemporal resolutions. To do so, we apply a parametric approach to statistically downscaled climate model outputs that reflect the Representative Concentration Pathway 8.5, which are offered by the North American Coordinated Regional Downscaling Experiment. Compared to traditional IDF estimation techniques, the employed framework is based on multifractal (MF) scaling arguments and assumes that the statistical structure of rainfall at interannual scales can be approximated by sequential realizations of a stationary MF process with parameters that vary slowly across (not within) realizations. The obtained results show that return period estimates exhibit significant downward trends over most of the domain, which slowly dampen with time, as the effects of climate change are more pronounced at lower exceedance probability levels. Given the observed rate of changes in the frequency and intensity of extreme rainfall for the remainder of the century, we argue that future infrastructure design should be strategically tailored to account for a wide range of potential outcomes. Key Points: We apply a robust multifractal scheme to sequential segments of downscaled NA‐CORDEX data and evaluate future changes in extreme rainfallUpward extreme rainfall trends dampen with time, as the effects of climate change are more distinct at lower exceedance probability levelsStrategically planned systems could encompass a large spectrum of possible rainfall intensification outcomes for the rest of the century [ABSTRACT FROM AUTHOR]
- Published
- 2023
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16. An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season.
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Gallagher, Rachael V., Allen, Stuart P., Mackenzie, Berin D. E., Keith, David A., Nolan, Rachael H., Rumpff, Libby, Gosper, Carl R., Pegg, Geoffrey, van Leeuwen, Stephen, Ooi, Mark K. J., Yates, Colin J., Merow, Cory, Williams, Richard J., Nikolopoulos, Efthymios I., Beaumont, Linda J., Auld, Tony D., and Varner, Morgan
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PLANT species ,NUMBERS of species ,DROUGHTS ,FIRE management ,PLANT populations ,ENDANGERED species ,DROUGHT management ,PLANT diversity - Abstract
Aim: Existing abiotic and biotic threats to plant species (e.g., disease, drought, invasive species) affect their capacity to recover post‐fire. We use a new, globally applicable framework to assess the vulnerability of 26,062 Australian plant species to a suite of active threats after the 2019–2020 fires. Location: Australia. Time period: 2019–2020. Major species studied: Plants. Methods: Spatial data for existing threats and information on species‐level susceptibility were combined with estimates of the extent of range burnt in southern Australia (> 22°S) to assign species against 10 criteria into vulnerability categories (high, medium, low, none, data deficient). We explore in detail results for three threats (drought, disease, feral animals), highlighting where impacts from multiple threats ranked high vulnerability may compound to reduce post‐fire recovery. Results: Analysis of the full suite of 10 vulnerability criteria, which encompass a broad range of threats, revealed large numbers of species vulnerable to poor post‐fire recovery from one or more different hazards (high vulnerability: 1,243 species; medium vulnerability: 2,450 species). Collectively, 457 plant species that burnt extensively (> 50%) across their range are highly vulnerable to poor recovery due to exposure to pre‐fire drought conditions (235 species), disease (186 species), or feral animals (97 species). Of these 457 species, 61 are vulnerable to more than one of these three threats, highlighting how a suite of interacting hazards can impact plant recovery after fire. Main conclusions: While fire can renew plant populations by stimulating recruitment and resetting competitive interactions, the presence of existing threats in post‐fire landscapes jeopardizes recovery. The simultaneous impact of multiple threats that impact recovery can create a suite of hazards that contribute to declines and, potentially, extinction. Our method for rapid post‐fire vulnerability assessment can be applied to large numbers of plant species or other biota in fire affected regions globally. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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17. The Spatiotemporal Evolution of Rainfall Extremes in a Changing Climate: A CONUS‐Wide Assessment Based on Multifractal Scaling Arguments.
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Emmanouil, Stergios, Langousis, Andreas, Nikolopoulos, Efthymios I., and Anagnostou, Emmanouil N.
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CLIMATE extremes ,CLIMATE change ,FLOOD risk ,ATMOSPHERIC models ,RAINFALL frequencies - Abstract
Given the rapidly changing climate, accurate spatiotemporal information on the evolution of extreme rainfall events is required for flood risk assessment and the design of resilient infrastructure. Consequently, various research efforts have focused on investigating the appropriateness of various parametric and non‐parametric approaches in modeling the observed changes in the frequency of extreme rainfall over time. Yet, the assumption of stationarity, or the change of model parameters when accounting for nonstationary rainfall, may magnify estimation uncertainty of rain rates associated with low exceedance probabilities. Moreover, the use of climate model results may yield inconclusive outcomes, given the existence of epistemic uncertainties in the frequency of extreme events developing on smaller spatial scales or over complex terrain. Herein, we employ a parametric approach based on multifractal scaling arguments, along with high‐resolution (4‐km) hourly precipitation estimates covering a 40‐year period over CONUS, to derive Intensity‐Duration‐Frequency curves and investigate the spatiotemporal evolution of extreme rainfall over a wide range of characteristic temporal scales and exceedance probability levels. Considering the robustness of the multifractal models even when fitted to short rainfall records, we uniquely apply the framework to sequential 10‐year segments of data, where the rainfall process can be reasonably assumed stationary. The obtained results reveal that existing infrastructure may be severely impacted by the intensification of precipitation extremes due to climate change, with the observed trends being significantly influenced by the topography and rainfall climatology of each region, while depending on the averaging durations and return periods of interest. Key Points: A robust multifractal scheme is applied to sequential data segments to assess the evolution of Intensity‐Duration‐Frequency curvesThe spatiotemporal evolution of extreme rainfall for various averaging durations and return periods reveals infrastructure vulnerabilitiesThe observed extreme rainfall trends are significantly influenced by local topography and rainfall climatology [ABSTRACT FROM AUTHOR]
- Published
- 2022
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18. Impact of compound flood event on coastal critical infrastructures considering current and future climate.
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Khanam, Mariam, Sofia, Giulia, Koukoula, Marika, Lazin, Rehenuma, Nikolopoulos, Efthymios I., Shen, Xinyi, and Anagnostou, Emmanouil N.
- Subjects
WEATHER forecasting ,METEOROLOGICAL research ,EMERGENCY management ,EFFECT of human beings on climate change ,WEATHER ,STORM surges ,FLOOD risk - Abstract
The changing climate and anthropogenic activities raise the likelihood of damage due to compound flood hazards, triggered by the combined occurrence of extreme precipitation and storm surge during high tides and exacerbated by sea-level rise (SLR). Risk estimates associated with these extreme event scenarios are expected to be significantly higher than estimates derived from a standard evaluation of individual hazards. In this study, we present case studies of compound flood hazards affecting critical infrastructure (CI) in coastal Connecticut (USA). We based the analysis on actual and synthetic (considering future climate conditions for atmospheric forcing, sea-level rise, and forecasted hurricane tracks) hurricane events, represented by heavy precipitation and surge combined with tides and SLR conditions. We used the Hydrologic Engineering Center's River Analysis System (HEC-RAS), a two-dimensional hydrodynamic model, to simulate the combined coastal and riverine flooding of selected CI sites. We forced a distributed hydrological model (CREST-SVAS) with weather analysis data from the Weather Research and Forecasting (WRF) model for the synthetic events and from the National Land Data Assimilation System (NLDAS) for the actual events, to derive the upstream boundary condition (flood wave) of HEC-RAS. We extracted coastal tide and surge time series for each event from the National Oceanic and Atmospheric Administration (NOAA) to use as the downstream boundary condition of HEC-RAS. The significant outcome of this study represents the evaluation of changes in flood risk for the CI sites for the various compound scenarios (under current and future climate conditions). This approach offers an estimate of the potential impact of compound hazards relative to the 100-year flood maps produced by the Federal Emergency Management Agency (FEMA), which is vital to developing mitigation strategies. In a broader sense, this study provides a framework for assessing the risk factors of our modern infrastructure located in vulnerable coastal areas throughout the world. [ABSTRACT FROM AUTHOR]
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- 2021
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19. Satellite-derived foresummer drought sensitivity of plant productivity in Rocky Mountain headwater catchments: spatial heterogeneity and geological-geomorphological control.
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Wainwright, Haruko M, Steefel, Christoph, Trutner, Sarah D, Henderson, Amanda N, Nikolopoulos, Efthymios I, Wilmer, Chelsea F, Chadwick, K Dana, Falco, Nicola, Schaettle, Karl Bernard, Brown, James Bentley, Steltzer, Heidi, Williams, Kenneth H, Hubbard, Susan S, and Enquist, Brian J
- Published
- 2020
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20. Assessment of precipitation error propagation in multi-model global water resource reanalysis.
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Ehsan Bhuiyan, Md Abul, Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., Polcher, Jan, Albergel, Clément, Dutra, Emanuel, Fink, Gabriel, Martínez-de la Torre, Alberto, and Munier, Simon
- Subjects
WATER supply ,LONG-range weather forecasting ,METEOROLOGICAL precipitation ,ARTIFICIAL neural networks ,HYDROLOGIC models ,EVAPOTRANSPIRATION - Abstract
This study focuses on the Iberian Peninsula and investigates the propagation of precipitation uncertainty, and its interaction with hydrologic modeling, in global water resource reanalysis. Analysis is based on ensemble hydrologic simulations for a period spanning 11 years (2000–2010). To simulate the hydrological variables of surface runoff, subsurface runoff, and evapotranspiration, we used four land surface models (LSMs) – JULES (Joint UK Land Environment Simulator), ORCHIDEE (Organising Carbon and Hydrology In Dynamic Ecosystems), SURFEX (Surface Externalisée), and HTESSEL (Hydrology – Tiled European Centre for Medium-Range Weather Forecasts – ECMWF – Scheme for Surface Exchanges over Land) – and one global hydrological model, WaterGAP3 (Water – a Global Assessment and Prognosis). Simulations were carried out for five precipitation products – CMORPH (the Climate Prediction Center Morphing technique of the National Oceanic and Atmospheric Administration, or NOAA), PERSIANN (Precipitation Estimation from Remotely Sensed Information using Artificial Neural Networks), 3B42V(7), ECMWF reanalysis, and a machine-learning-based blended product. As a reference, we used a ground-based observation-driven precipitation dataset, named SAFRAN, available at 5 km, 1 h resolution. We present relative performances of hydrologic variables for the different multi-model and multi-forcing scenarios. Overall, results reveal the complexity of the interaction between precipitation characteristics and different modeling schemes and show that uncertainties in the model simulations are attributed to both uncertainty in precipitation forcing and the model structure. Surface runoff is strongly sensitive to precipitation uncertainty, and the degree of sensitivity depends significantly on the runoff generation scheme of each model examined. Evapotranspiration fluxes are comparatively less sensitive for this study region. Finally, our results suggest that there is no single model–forcing combination that can outperform all others consistently for all variables examined and thus reinforce the fact that there are significant benefits to exploring different model structures as part of the overall modeling approaches used for water resource applications. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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21. Evaluation of predictive models for post-fire debris flow occurrence in the western United States.
- Author
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Nikolopoulos, Efthymios I., Destro, Elisa, Bhuiyan, Md Abul Ehsan, Borga, Marco, and Anagnostou, Emmanouil N.
- Subjects
FIRE debris ,MASS casualties ,PREDICTION models ,RANDOM forest algorithms - Abstract
Rainfall-induced debris flows in recently burned mountainous areas cause significant economic losses and human casualties. Currently, prediction of post-fire debris flows is widely based on the use of power-law thresholds and logistic regression models. While these procedures have served with certain success in existing operational warning systems, in this study we investigate the potential to improve the efficiency of current predictive models with machinelearning approaches. Specifically, the performance of a predictive model based on the random forest algorithm is compared with current techniques for the prediction of post-fire debris flow occurrence in the western United States. The analysis is based on a database of post-fire debris flows recently published by the United States Geological Survey. Results show that predictive models based on random forest exhibit systematic and considerably improved performance with respect to the other models examined. In addition, the random-forest-based models demonstrated improvement in performance with increasing training sample size, indicating a clear advantage regarding their ability to successfully assimilate new information. Complexity, in terms of variables required for developing the predictive models, is deemed important but the choice of model used is shown to have a greater impact on the overall performance. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
22. A nonparametric statistical technique for combining global precipitation datasets: development and hydrological evaluation over the Iberian Peninsula.
- Author
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Bhuiyan, Md Abul Ehsan, Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., Quintana-Seguí, Pere, and Barella-Ortiz, Anaïs
- Subjects
METEOROLOGICAL precipitation ,HYDROLOGIC models ,SOIL moisture ,STREAMFLOW ,DATABASES - Abstract
This study investigates the use of a nonparametric, tree-based model, quantile regression forests (QRF), for combining multiple global precipitation datasets and characterizing the uncertainty of the combined product. We used the Iberian Peninsula as the study area, with a study period spanning 11 years (2000-2010). Inputs to the QRF model included three satellite precipitation products, CMORPH, PERSIANN, and 3B42 (V7); an atmospheric reanalysis precipitation and air temperature dataset; satellite-derived nearsurface daily soil moisture data; and a terrain elevation dataset. We calibrated the QRF model for two seasons and two terrain elevation categories and used it to generate ensemble for these conditions. Evaluation of the combined product was based on a high-resolution, ground-reference precipitation dataset (SAFRAN) available at 5 km1h
-1 resolution. Furthermore, to evaluate relative improvements and the overall impact of the combined product in hydrological response, we used the generated ensemble to force a distributed hydrological model (the SURFEX land surface model and the RAPID river routing scheme) and compared its streamflow simulation results with the corresponding simulations from the individual global precipitation and reference datasets. We concluded that the proposed technique could generate realizations that successfully encapsulate the reference precipitation and provide significant improvement in streamflow simulations, with reduction in systematic and random error on the order of 20-99 and 44-88 %, respectively, when considering the ensemble mean. [ABSTRACT FROM AUTHOR]- Published
- 2018
- Full Text
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23. Evaluation of High-Resolution Multisatellite and Reanalysis Rainfall Products over East Africa.
- Author
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Sahlu, Dejene, Moges, Semu A., Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., and Hailu, Dereje
- Subjects
RAINFALL probabilities ,RAINFALL ,RAINFALL intensity duration frequencies ,METEOROLOGICAL precipitation ,RAIN gauges - Abstract
The performance of six satellite-based and three newly released reanalysis rainfall estimates are evaluated at daily time scale and spatial grid size of 0.25 degrees during the period of 2000 to 2013 over the Upper Blue Nile Basin, Ethiopia, with the view of improving the reliability of precipitation estimates of the wet (June to September) and secondary rainy (March to May) seasons. The study evaluated both adjusted and unadjusted satellite-based products of TMPA, CMORPH, PERSIANN, and ECMWF ERA-Interim reanalysis as well as Multi-Source Weighted-Ensemble Precipitation (MSWEP) estimates. Among the six satellite-based rainfall products, adjusted CMORPH exhibits the best accuracy of the wet season rainfall estimate. In the secondary rainy season, unadjusted CMORPH and 3B42V7 are nearly equivalent in terms of bias, POD, and CSI error metrics. All error metric statistics show that MSWEP outperform both unadjusted and gauge adjusted ERA-Interim estimates. The magnitude of error metrics is linearly increasing with increasing percentile threshold values of gauge rainfall categories. Overall, all precipitation datasets need further improvement in terms of detection during the occurrence of high rainfall intensity. MSWEP detects higher percentiles values better than satellite estimate in the wet and poor in the secondary rainy seasons. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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- View/download PDF
24. Impact of rainfall spatial aggregation on the identification of debris flow occurrence thresholds.
- Author
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Marra, Francesco, Destro, Elisa, Nikolopoulos, Efthymios I., Zoccatelli, Davide, Creutin, Jean Dominique, Guzzetti, Fausto, and Borga, Marco
- Subjects
RAINFALL ,ATMOSPHERIC effects on remote sensing ,RAIN gauges ,WEATHER forecasting ,CLIMATE change - Abstract
The systematic underestimation observed in debris flow early warning thresholds has been associated with the use of sparse rain gauge networks to represent highly non-stationary rainfall fields. Remote sensing products permit concurrent estimates of debris-flow-triggering rainfall for areas poorly covered by rain gauges, but the impact of using coarse spatial resolutions to represent such rainfall fields is still to be assessed. This study uses fine-resolution radar data for ~100 debris flows in the eastern Italian Alps to (i) quantify the effect of spatial aggregation (1-20km grid size) on the estimation of debris-flow-triggering rainfall and on the identification of early warning thresholds and (ii) compare thresholds derived from aggregated estimates and rain gauge networks of different densities. The impact of spatial aggregation is influenced by the spatial organization of rainfall and by its dependence on the severity of the triggering rainfall. Thresholds from aggregated estimates show 8-21% variation in the parameters whereas 10-25% systematic variation results from the use of rain gauge networks, even for densities as high as 1/10km
-2 . [ABSTRACT FROM AUTHOR]- Published
- 2017
- Full Text
- View/download PDF
25. Modeling Satellite Precipitation Errors Over Mountainous Terrain: The Influence of Gauge Density, Seasonality, and Temporal Resolution.
- Author
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Maggioni, Viviana, Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., and Borga, Marco
- Subjects
- *
METEOROLOGICAL precipitation , *NATURAL satellites , *HYDROLOGY , *METEOROLOGICAL observations , *RAINFALL intensity duration frequencies - Abstract
This paper contributes to the predictive understanding of satellite precipitation estimation errors over complex terrain, which is fundamental to the development of error models for improving hydrological applications. This paper focuses on the Trentino-Alto Adige region of the eastern Italian Alps. Rainfall observations over a 10-year period (2000–2009) from a dense rain gauge network in the region are used as reference precipitation. A number of satellite precipitation error properties (probability of detection, false alarm rates, missed events, spatial correlation of the error, and hit biases) are investigated in terms of seasonality, satellite algorithm, rainfall intensity, gauge density, and temporal resolution dependencies. These error parameters are typically used in error models (e.g., SREM2D) and provide the basis for enhancing error scheme development. Three widely used satellite-based precipitation products are employed: 1) the Climate Prediction Center morphing product; 2) the precipitation estimation from remotely sensed imagery using artificial neural networks; and 3) the Tropical Rainfall Measuring Mission multisatellite precipitation analysis 3B42 near-real-time product. The three products show similar performances, with larger errors during the warm season, characterized by convective storms, and less variability in the cold season, characterized by more organized stratiform systems. Lower biases are depicted at the daily scale with respect to the 3-hourly resolution. The SREM2D error model has the ability to correct the satellite precipitation products, even though attention is needed for potential systematic errors when applying the calibrated model to independent periods or regions. [ABSTRACT FROM PUBLISHER]
- Published
- 2017
- Full Text
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26. Error Analysis of Satellite Precipitation-Driven Modeling of Flood Events in Complex Alpine Terrain.
- Author
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Yiwen Mei, Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., Zoccatelli, Davide, and Borga, Marco
- Subjects
- *
FLOODS , *RUNOFF , *GEOLOGICAL basins , *HYDROGRAPHY , *HYDROLOGY - Abstract
The error in satellite precipitation-driven complex terrain flood simulations is characterized in this study for eight different global satellite products and 128 flood events over the Eastern Italian Alps. The flood events are grouped according to two flood types: rain floods and flash floods. The satellite precipitation products and runoff simulations are evaluated based on systematic and random error metrics applied on the matched event pairs and basin-scale event properties (i.e., rainfall and runoff cumulative depth and time series shape). Overall, error characteristics exhibit dependency on the flood type. Generally, timing of the event precipitation mass center and dispersion of the time series derived from satellite precipitation exhibits good agreement with the reference; the cumulative depth is mostly underestimated. The study shows a dampening effect in both systematic and random error components of the satellite-driven hydrograph relative to the satellite-retrieved hyetograph. The systematic error in shape of the time series shows a significant dampening effect. The random error dampening effect is less pronounced for the flash flood events and the rain flood events with a high runoff coefficient. This event-based analysis of the satellite precipitation error propagation in flood modeling sheds light on the application of satellite precipitation in mountain flood hydrology. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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- View/download PDF
27. Unmanned Aerial Systems-Aided Post-Flood Peak Discharge Estimation in Ephemeral Streams.
- Author
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Andreadakis, Emmanouil, Diakakis, Michalis, Vassilakis, Emmanuel, Deligiannakis, Georgios, Antoniadis, Antonis, Andriopoulos, Petros, Spyrou, Nafsika I., and Nikolopoulos, Efthymios I.
- Subjects
GLOBAL Positioning System ,EPHEMERAL streams ,HYDROLOGICAL surveys ,UNCERTAINTY - Abstract
The spatial and temporal scale of flash flood occurrence provides limited opportunities for observations and measurements using conventional monitoring networks, turning the focus to event-based, post-disaster studies. Post-flood surveys exploit field evidence to make indirect discharge estimations, aiming to improve our understanding of hydrological response dynamics under extreme meteorological forcing. However, discharge estimations are associated with demanding fieldwork aiming to record in small timeframes delicate data and data prone-to-be-lost and achieve the desired accuracy in measurements to minimize various uncertainties of the process. In this work, we explore the potential of unmanned aerial systems (UAS) technology, in combination with the Structure for Motion (SfM) and optical granulometry techniques in peak discharge estimations. We compare the results of the UAS-aided discharge estimations to estimates derived from differential Global Navigation Satellite System (d-GNSS) surveys and hydrologic modelling. The application in the catchment of the Soures torrent in Greece, after a catastrophic flood, shows that the UAS-aided method determined peak discharge with accuracy, providing very similar values compared to the ones estimated by the established traditional approach. The technique proved to be particularly effective, providing flexibility in terms of resources and timing, although there are certain limitations to its applicability, related mostly to the optical granulometry as well as the condition of the channel. The application highlighted important advantages and certain weaknesses of these emerging tools in indirect discharge estimations, which we discuss in detail. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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- View/download PDF
28. Sensitivity of flood frequency analysis to data record, statistical model, and parameter estimation methods: An evaluation over the contiguous United States.
- Author
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Hu, Lanxin, Nikolopoulos, Efthymios I., Marra, Francesco, and Anagnostou, Emmanouil N.
- Subjects
PARAMETER estimation ,STATISTICAL models ,MAXIMUM likelihood statistics ,DATA analysis ,EVALUATION methodology - Abstract
The current statistical methods applied in flood frequency analysis require long data records to obtain reliable estimates, particularly for long return periods. Moreover, the choice of the statistical model and the parameter estimation procedure may introduce uncertainty in the estimates. In this work, we investigate the sensitivity of flood frequency analysis to various sample sizes, statistical models, and parameter estimation methods over six major hydrological regions in the contiguous United States. Results show that flood frequency estimates based on annual maximum series approach convergence to the reference values (estimates derived from 70 years record) in terms of median for 35‐year or longer records. However, the uncertainty remains significant and a record of 35 years (20 years) is associated with ~50% (100%) larger uncertainty on the estimated 100‐year flood. The generalised extreme value distribution combined with maximum likelihood estimation method is associated with the largest uncertainty, while the log‐Pearson type III exhibits comparable bias and smaller uncertainty. Application of the partial duration series approach to 20‐year records shows no significant advantage. Our findings suggest that the hydroclimatic characteristics of the catchments exhibit limited impact on the uncertainty. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
29. Evaluation of GPM-era Global Satellite Precipitation Products over Multiple Complex Terrain Regions.
- Author
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Derin, Yagmur, Anagnostou, Emmanouil, Berne, Alexis, Borga, Marco, Boudevillain, Brice, Buytaert, Wouter, Chang, Che-Hao, Chen, Haonan, Delrieu, Guy, Hsu, Yung Chia, Lavado-Casimiro, Waldo, Manz, Bastian, Moges, Semu, Nikolopoulos, Efthymios I., Sahlu, Dejene, Salerno, Franco, Rodríguez-Sánchez, Juan-Pablo, Vergara, Humberto J., and Yilmaz, Koray K.
- Subjects
PRECIPITATION gauges ,RAIN gauges ,WATER vapor ,ARTIFICIAL satellites ,WATER supply ,CLASSIFICATION algorithms ,RAINFALL - Abstract
The great success of the Tropical Rainfall Measuring Mission (TRMM) and its successor Global Precipitation Measurement (GPM) has accelerated the development of global high-resolution satellite-based precipitation products (SPP). However, the quantitative accuracy of SPPs has to be evaluated before using these datasets in water resource applications. This study evaluates the following GPM-era and TRMM-era SPPs based on two years (2014–2015) of reference daily precipitation data from rain gauge networks in ten mountainous regions: Integrated Multi-SatellitE Retrievals for GPM (IMERG, version 05B and version 06B), National Oceanic and Atmospheric Administration (NOAA)/Climate Prediction Center Morphing Method (CMORPH), Global Satellite Mapping of Precipitation (GSMaP), and Multi-Source Weighted-Ensemble Precipitation (MSWEP), which represents a global precipitation data-blending product. The evaluation is performed at daily and annual temporal scales, and at 0.1 deg grid resolution. It is shown that GSMaPV07 surpass the performance of IMERGV06B Final for almost all regions in terms of systematic and random error metrics. The new orographic rainfall classification in the GSMaPV07 algorithm is able to improve the detection of orographic rainfall, the rainfall amounts, and error metrics. Moreover, IMERGV05B showed significantly better performance, capturing the lighter and heavier precipitation values compared to IMERGV06B for almost all regions due to changes conducted to the morphing, where motion vectors are derived using total column water vapor for IMERGV06B. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
30. Advancing Precipitation Estimation and Streamflow Simulations in Complex Terrain with X-Band Dual-Polarization Radar Observations.
- Author
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Anagnostou, Marios N., Nikolopoulos, Efthymios I., Kalogiros, John, Anagnostou, Emmanouil N., Marra, Francesco, Mair, Elisabeth, Bertoldi, Giacomo, Tappeiner, Ulrike, and Borga, Marco
- Subjects
- *
METEOROLOGICAL precipitation , *STREAMFLOW , *POLARIZATION (Nuclear physics) , *RAINFALL , *REMOTE sensing - Abstract
In mountain basins, the use of long-range operational weather radars is often associated with poor quantitative precipitation estimation due to a number of challenges posed by the complexity of terrain. As a result, the applicability of radar-based precipitation estimates for hydrological studies is often limited over areas that are in close proximity to the radar. This study evaluates the advantages of using X-band polarimetric (XPOL) radar as a means to fill the coverage gaps and improve complex terrain precipitation estimation and associated hydrological applications based on a field experiment conducted in an area of Northeast Italian Alps characterized by large elevation differences. The corresponding rainfall estimates from two operational C-band weather radar observations are compared to the XPOL rainfall estimates for a near-range (10–35 km) mountainous basin (64 km2). In situ rainfall observations from a dense rain gauge network and two disdrometers (a 2D-video and a Parsivel) are used for ground validation of the radar-rainfall estimates. Ten storm events over a period of two years are used to explore the differences between the locally deployed XPOL vs. longer-range operational radar-rainfall error statistics. Hourly aggregate rainfall estimates by XPOL, corrected for rain-path attenuation and vertical reflectivity profile, exhibited correlations between 0.70 and 0.99 against reference rainfall data and 21% mean relative error for rainfall rates above 0.2 mm h−1. The corresponding metrics from the operational radar-network rainfall products gave a strong underestimation (50–70%) and lower correlations (0.48–0.81). For the two highest flow-peak events, a hydrological model (Kinematic Local Excess Model) was forced with the different radar-rainfall estimations and in situ rain gauge precipitation data at hourly resolution, exhibiting close agreement between the XPOL and gauge-based driven runoff simulations, while the simulations obtained by the operational radar rainfall products resulted in a greatly underestimated runoff response. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
31. Analysis of intensity-duration-frequency curves derived from NEXRAD-based quantitative precipitation estimates over CONUS.
- Author
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McGraw, Daniel, Nikolopoulos, Efthymios I., and Anagnostou, Emmanouil N.
- Subjects
- *
CONUS , *RAINFALL intensity duration frequencies , *METEOROLOGICAL precipitation , *FREQUENCY curves , *ESTIMATES - Published
- 2018
32. GDBC: A tool for generating global-scale distributed basin morphometry.
- Author
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Shen, Xinyi, Vergara, Humberto J., Nikolopoulos, Efthymios I., Anagnostou, Emmanouil N., Hong, Yang, Hao, Zengchao, Zhang, Ke, and Mao, Kebiao
- Subjects
- *
GEOMORPHOLOGY , *HAZARDS , *HYDROLOGY , *MORPHOMETRICS , *SURFACE of the earth , *COMPUTER algorithms - Abstract
In response to the vital role of geomorphological analysis in natural hazards study, geomorphology, distributed hydrology and other related disciplines, we present the first global basin morphometric product of 30 characteristics, 9 archived elementary including stream order, stream number, stream length, basin relief, basin length, basin perimeter, maximal flow length, down valley length and overland flow length, and 21 derivable from these elementary morphometric characteristics. Characteristics of basins discharging to every grid-cell of the global earth surface are generated at 30 arcsec resolution from the remotely sensed HydroSHEDS dataset. This product does not exist in previous literature because tree-structural grid-cells bring large computational redundancy to basin delineation and thus computing basin characteristics. To generate this product within a reasonable timeframe, we introduce in this paper an efficient framework to reduce the algorithm complexity to linear, O( N ). We have presented a few geomorphologic findings using the generated product. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
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