Three techniques for flow component identification from daily discharge data in Madjez Ressoul catchment, Algeria

High flow events are the main prerequisites for floods with negative social and environmental consequences. Their study under uncertain and changing climate gives informative knowledge for further management decisions. This paper seeks to analyze the spatio-temporal parameters of high flow periods within the Danube drainage basin in Bulgaria. Three characteristics of the hazard phenomena: time of occurring, frequency and duration are investigated. The analysis is based on daily discharge data collected from 20 gauging stations for the period 2000–2005. The surplus water quantities are identified by the Threshold level method using fixed values – Q25 and Q5, derived from the flow duration curve. Results show a concentration of the high flow periods during the spring hydrological season, with an average duration up to six weeks. The calculations establish positive correlations between the duration of high flow, the altitude of catchments, and the density of drainage network. The resulting information can serve as a support for the development of preliminary flood risk assessments in the Danube River Basin.

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Multi-variate infilling of missing daily discharge data on the Niger basin

Water Practice & Technology ◽

10.2166/wpt.2021.048 ◽

2021 ◽

Author(s):

Ganiyu Titilope Oyerinde ◽

Agnide E. Lawin ◽

Oluwafemi E. Adeyeri

Keyword(s):

Missing Data ◽

River Discharge ◽

Missing Values ◽

Spatial Scales ◽

Gap Filling ◽

Discharge Data ◽

Flow Duration ◽

Daily Discharge ◽

Flow Duration Curves ◽

Discharge Patterns

Abstract The Niger basin have experienced historical drought episodes and floods in recent times. Reliable hydrological modelling has been hampered by missing values in daily river discharge data. We assessed the potential of using the Multivariate Imputation by Chained Equations (MICE) to estimate both continuous and discontinuous daily missing data across different spatial scales in the Niger basin. The study was conducted on 22 discharge stations that have missing data ranging from 2% to 70%. Four efficiency metrics were used to determine the effectiveness of MICE. The Flow Duration Curves (FDC) of observed and filled data were compared to determine how MICE captured the discharge patterns. Mann-Kendall, Modified Mann-Kendall, Pettit and Sen's Slope were used to assess the complete discharge trends using the gap-filled data. Results shows that MICE near perfectly filled the missing discharge data with Nash-Sutcliffe Efficiency (NSE) range of 0.94–0.99 for the calibration (1992–1994) period. Good fits were obtained between FDC of observed and gap-filled data in all considered stations. All the catchments showed significantly increasing discharge trend since 1990s after gap filling. Consequently, the use of MICE in handling missing data challenges across spatial scales in the Niger basin was proposed.

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The African Database of Hydrometric Indices (ADHI)

10.5194/essd-2020-281 ◽

2020 ◽

Author(s):

Yves Tramblay ◽

Nathalie Rouché ◽

Jean-Emmanuel Paturel ◽

Gil Mahé ◽

Jean-François Boyer ◽

...

Keyword(s):

Quality Control ◽

River Discharge ◽

Scientific Community ◽

Flow Characteristics ◽

African Continent ◽

Mean Flow ◽

Discharge Data ◽

Daily Discharge ◽

The One ◽

Different Sources

Abstract. The African continent is probably the one with the lowest density of hydrometric stations currently measuring river discharge, despite the fact that the number of operating stations was quite important until the 70s. This new African Database of Hydrometric Indices (ADHI) is compiling data from different sources carefully checked for quality control. It includes about 1500 stations with at least 10 years of daily discharge data over the period 1950–2018. The average record length is 19 years and for over 100 stations complete records are available over 50 years. With this dataset spanning most regions of the African continent, several hydrometric indices have been computed, representing mean flow characteristics and extremes (low flows and floods), and are made accessible to the scientific community. The database will be updated on a regular basis to include more hydrometric stations and longer time series of river discharge. The ADHI database is available for download at: https://doi.org/10.23708/LXGXQ9 (Tramblay and Rouché, 2020).

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ADHI: the African Database of Hydrometric Indices (1950–2018)

Earth System Science Data ◽

10.5194/essd-13-1547-2021 ◽

2021 ◽

Vol 13 (4) ◽

pp. 1547-1560

Author(s):

Yves Tramblay ◽

Nathalie Rouché ◽

Jean-Emmanuel Paturel ◽

Gil Mahé ◽

Jean-François Boyer ◽

...

Keyword(s):

River Discharge ◽

Flow Characteristics ◽

African Continent ◽

Mean Flow ◽

Discharge Data ◽

Climatic Regions ◽

Wide Range ◽

Daily Discharge ◽

The One ◽

Different Sources

Abstract. The African continent is probably the one with the lowest density of hydrometric stations currently measuring river discharge despite the fact that the number of operating stations was quite important until the 1970s. This new African Database of Hydrometric Indices (ADHI) provides a wide range of hydrometric indices and hydrological signatures computed from different sources of data after a quality control. It includes 1466 stations with at least 10 years of daily discharge data over the period 1950–2018. The average record length is 33 years, and 131 stations have complete records over 50 years. With this new dataset spanning most climatic regions of the African continent, several hydrometric indices have been computed, representing mean flow characteristics and extremes (low flows and floods), and are accessible to the scientific community. The database will be updated on a regular basis to include more hydrometric stations and longer time series of river discharge. The ADHI is available for download at: https://doi.org/10.23708/LXGXQ9 (Tramblay and Rouché, 2020).

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Discharge estimation and monitoring extreme events by satellite altimetry

10.5194/egusphere-egu2020-8020 ◽

2020 ◽

Author(s):

Rossella Belloni ◽

Stefania Camici ◽

Angelica Tarpanelli

Keyword(s):

Time Series ◽

Water Level ◽

River Discharge ◽

Satellite Altimetry ◽

Global Scale ◽

Discharge Time ◽

Discharge Data ◽

The World ◽

Daily Discharge ◽

Rating Curves

In view of recent dramatic floods and drought events, the detection of trends in the frequency and magnitude of long time series of flood data is of scientific interest and practical importance. It is essential in many fields, from climate change impact assessment to water resources management, from flood forecasting to drought monitoring, for the planning of future water resources and flood protection systems.&#160; To detect long-term changes in river discharge a dense, in space and time, network of monitoring stations is required. However, ground hydro-meteorological monitoring networks are often missing or inadequate in many parts of the world and the global supply of the available river discharge data is often restricted, preventing to identify trends over large areas. &#160; The most direct method of deriving such information on a global scale involves satellite earth observation. Over the last two decades, the growing availability of satellite sensors, and the results so far obtained in the estimation of river discharge from the monitoring of the water level through satellite radar altimetry has fostered the interest on this subject. &#160; Therefore, in the attempt to overcome the lack of long continuous observed time series, in this study satellite altimetry water level data are used to set-up a consistent, continuous and up-to-date daily discharge dataset for different sites across the world. Satellite-derived water levels provided by publicly available datasets (Podaac, Dahiti, River& Lake, Hydroweb and Theia) are used along with available ground observed river discharges to estimate rating curves. Once validated, the rating curves are used to fill and extrapolate discharge data over the whole period of altimetry water level observations. The advantage of using water level observations provided by the various datasets allowed to obtain discharge time series with improved spatio-temporal coverages and resolutions, enabling to extend the study on a global scale and to efficiently perform the analysis even for small to medium-sized basins. &#160; Long continuous discharge time series so obtained are used to perform a global trend analysis on extreme flood and drought events. Specifically, annual maximum discharge and peak-over threshold values are extracted from the simulated daily discharge time series, as proxy variables of independent flood events. For flood and drought events, a trend analysis is carried out to identify changes in the frequency and magnitude of extreme events through the Mann-Kendall (M-K) test and a linear regression model between time and the flood magnitude. &#160; The analysis has permitted to identify areas of the world prone to floods and drought, so that appropriate actions for disaster risk mitigation and continuous improvement in disaster preparedness, response, and recovery practices can be adopted.&#160;

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Analysis of extreme hydrological Events on THE danube using the Peak Over Threshold method

Journal of Hydrology and Hydromechanics ◽

10.2478/v10098-010-0009-x ◽

2010 ◽

Vol 58 (2) ◽

pp. 88-101 ◽

Cited By ~ 22

Author(s):

Veronika Bačová-Mitková ◽

Milan Onderka

Keyword(s):

Danube River ◽

Data Series ◽

Time Data ◽

Threshold Method ◽

Series Length ◽

Discharge Data ◽

Peak Over Threshold ◽

Peak Over Threshold Method ◽

Daily Discharge ◽

Extreme Hydrological Events

Analysis of extreme hydrological Events on THE danube using the Peak Over Threshold methodThe Peak Over Threshold Method (POT) was used as an alternative technique to the traditional analysis of annual discharge maxima of the Danube River. The POT method was applied to a time-series of daily discharge values covering a period of 60 years (1931-1990) at the following gauge stations: Achleiten, Kienstock, Wien, Bratislava and Nagymaros. The first part of the paper presents the use of the POT method and how it was applied to daily discharges. All mean daily discharges exceeding a defined threshold were considered in the POT analysis. Based on the POT waves independence criteria the maximum daily discharge data were selected. Two theoretical log-normal (LN) and Log-Pearson III (LP3) distributions were used to calculate the probability of exceeding annual maximum discharges. Performance of the POT method was compared to the theoretical distributions (LN, LP3). The influence of the data series length on the estimation of theN-year discharges by POT method was carried out too. Therefore, with regard to later regulations along the Danube channel bank the 40, 20 and 10-year time data series were chosen in early of the 60-year period and second analysed time data series were selected from the end of the 60-year period. Our results suggest that the POT method can provide adequate and comparable estimates ofN-year discharges for more stations with short temporal coverage.

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KAJIAN PENGARUH SITU TERHADAP RESPON HIDROLOGI DI DAS PESANGGRAHAN MENGGUNAKAN MODEL HEC-HMS

Jurnal Ilmu Tanah dan Lingkungan ◽

10.29244/jitl.12.2.11-17 ◽

2010 ◽

Vol 12 (2) ◽

pp. 11

Author(s):

Selamet Kusdaryanto ◽

Dwi Putro Tejo Baskoro ◽

Suria Darma Tarigan

Keyword(s):

Model Calibration ◽

Local Effect ◽

Peak Discharge ◽

Hydrological Response ◽

Reservoir Capacity ◽

Discharge Data ◽

Rainfall Condition ◽

Run Off ◽

Capacity Change ◽

Daily Discharge

Pesanggrahan river with total extent of watershed about 13,384 ha is one of rivers flowing through Jakarta City that causes flood problem every years. Many effort has been done to reduce flood problem, among others is to build reservoir in watershed, but the effectiveness of reservoir is still questionable. A research aimed to analyze gap of reservoir capacity changes and its influence on hydrological response and to arrange the scenario of reservoir capacity change to improve hydrological response in Pesanggrahan Watershed was done using HEC-HMS Model. Reservoir capacity change scenarios applied to the actual rainfall condition and designed rainfall condition with a certain recurrence interval. The scenarios consist of: reservoir with the exsisting condition (scenario 1), increase depth of reservoir to 5 meters (scenario 2) and build 6 reservoirs on Pesanggrahan watershed (scenario 3). The model was calibrated using daily discharge data from the date of January 10th to April 30th 2009. Model calibration result shows that model is quite accurate to predict peak discharge in Pesanggrahan Watershed with Nash-Sutcliffe efficiency value = 0.9817 and R2 =0.975. Simulation results showed that the reservoir is effective in decreasing its local effect to peak discharge (reservoir area). The presence of reservoir with existing condition reduce only 6.38 % of the peak run off in outlet Kebon jeruk, whereas building of 6 reservoir will reduce 24.6 % of the peak run off in outlet Kebon jeruk. Keywords : HEC-HMS Model, peak discharge, Reservoir capacity change

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ADHI: The African Database of Hydrometric Indices (1950-2018)

10.5194/egusphere-egu21-9283 ◽

2021 ◽

Author(s):

Nathalie Rouché ◽

Yves Tramblay ◽

Jean-Emmanuel Paturel ◽

Gil Mahé ◽

Jean-François Boyer ◽

...

Keyword(s):

Time Series ◽

Missing Data ◽

River Discharge ◽

Data Availability ◽

Eastern Africa ◽

African Continent ◽

Discharge Data ◽

Daily Discharge ◽

Time Periods ◽

Different Sources

The African continent is probably the one with the lowest density of hydrometric stations currently measuring river discharge, despite the fact that the number of stations was quite important until the 70s. In addition, there is a major issue of data availability, since the different existing datasets are scattered across vast regions, heterogeneous and often with a large amount of missing data in the time series. The aim of this African Dataset of Hydrometric Indices (ADHI) is to provide a set of hydrometric indices computed from an unprecedented large set of daily discharge data in Africa. The ADHI database is based on a new streamflow dataset of 1466 gauging stations with an average record length of 33 years and for over 100 stations complete records are available over 50 years. ADHI is compiling data from different sources carefully checked, based on the historical databases of ORSTOM / IRD and the GRDC, including also other contributions from different countries and basin agencies. The criterion for a station to be included in ADHI is to have a minimum of 10 full years of daily discharge data between 1950 and 2018 with less than 5% missing data. Some time series originating from different sources were concatenated, after making sure the rating curves applied on the different time periods to compute river discharge were similar. Data records were scrutinized to identify suspicious discharge records and time periods where gap-filling methods have been applied to the original records. The selected stations are spread across the whole African continent, with the highest density in Western and Southern Africa and the lowest density in Eastern Africa. They are representative of most of the climate zones of Africa according the K&#246;ppen-Geiger climate classification. From this dataset, a large range of hydrological indices and flow signatures have been computed and made available to the scientific community (https://doi.org/10.23708/LXGXQ9). They are representing mean flow characteristics and extremes (low flows and floods) but also catchment characteristics, allowing to study the long-term evolution of hydrology in Africa and support the modelling efforts that aim at reducing the vulnerability of African countries to hydro-climatic variability.

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Recent Trends in Freshwater Influx to the Arctic Ocean from Four Major Arctic-Draining Rivers

Water ◽

10.3390/w12041189 ◽

2020 ◽

Vol 12 (4) ◽

pp. 1189 ◽

Cited By ~ 1

Author(s):

Roxanne Ahmed ◽

Terry Prowse ◽

Yonas Dibike ◽

Barrie Bonsal ◽

Hayley O’Neil

Keyword(s):

Arctic Ocean ◽

Thermohaline Circulation ◽

Global Climate ◽

Ocean Dynamics ◽

The Arctic ◽

Freshwater Input ◽

Discharge Data ◽

The Arctic Ocean ◽

Spring Freshet ◽

Daily Discharge

Runoff from Arctic rivers constitutes a major freshwater influx to the Arctic Ocean. In these nival-dominated river systems, the majority of annual discharge is released during the spring snowmelt period. The circulation regime of the salinity-stratified Arctic Ocean is connected to global earth–ocean dynamics through thermohaline circulation; hence, variability in freshwater input from the Arctic flowing rivers has important implications for the global climate system. Daily discharge data from each of the four largest Arctic-draining river watersheds (Mackenzie, Ob, Lena and Yenisei; herein referred to as MOLY) are analyzed to identify historic changes in the magnitude and timing of freshwater input to the Arctic Ocean with emphasis on the spring freshet. Results show that the total freshwater influx to the Arctic Ocean increased by 89 km3/decade, amounting to a 14% increase during the 30-year period from 1980 to 2009. A distinct shift towards earlier melt timing is also indicated by proportional increases in fall, winter and spring discharges (by 2.5%, 1.3% and 2.5% respectively) followed by a decrease (by 5.8%) in summer discharge as a percentage of the mean annual flow. This seasonal increase in discharge and earlier pulse onset dates indicates a general shift towards a flatter, broad-based hydrograph with earlier peak discharges. The study also reveals that the increasing trend in freshwater discharge to the Arctic Ocean is not solely due to increased spring freshet discharge, but is a combination of increases in all seasons except that of the summer.

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Characterization of karstic aquifer complexity using fractal dimensions

GEM - International Journal on Geomathematics ◽

10.1007/s13137-020-00169-5 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Edit Borbás ◽

László Márkus ◽

Amina Darougi ◽

József Kovács

Keyword(s):

Fractal Dimensions ◽

The Other ◽

Data Series ◽

Water Migration ◽

Karstic Aquifer ◽

Discharge Data ◽

Water Flows ◽

Daily Discharge ◽

The Given

AbstractThe present study analyzes fractal dimensions for the daily discharge data series of 12 karstic springs registered over two decades in Northeast Hungary. Fluctuation in the observed data is frequent and irregular, producing rough time series. The level of roughness is measured by the fractal dimension defined in different ways and corresponds to the intensity of fluctuation. That, in turn, results from the structure of the karstic aquifer, its conduits’ geometry, and the water migration in them. In the given case of springs, p-variogram based fractal dimensions reflect the karstification level primarily. On the other hand, box-count and information dimensions are associated with mixing karstic and hydrothermal components when the latter is present. Therefore, the analysis of fractal dimensions of spring discharges may provide a way to obtain information on the complexity of the hidden subsurface conduits and the water flows in them in an exploratory and comprehensive way.

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