Your search keyword '"G. R. Brakenridge"' showing total 4 results

1. L-Band Passive Microwave Data from SMOS for River Gauging Observations in Tropical Climates

Author

G. R. Brakenridge, Son V. Nghiem, and Zsofia Kugler

Subjects

L band, 010504 meteorology & atmospheric sciences, satellite gauging, GFDS, 0208 environmental biotechnology, hydrology, 02 engineering and technology, 01 natural sciences, times series, altimetry, Altimeter, lcsh:Science, 0105 earth and related environmental sciences, Remote sensing, tropical climate, Vegetation, 020801 environmental engineering, Water level, General Earth and Planetary Sciences, Environmental science, Satellite, lcsh:Q, Stage (hydrology), Global Precipitation Measurement, Microwave, SMOS

Abstract

The Global Flood Detection Systems (GFDS) currently operated at the European Commission’s Joint Research Centre (JRC) is a satellite-based observation system that provides daily stream flow measurements of global rivers. The system was initially established using NASA Advanced Microwave Scanning Radiometer—Earth Observing System (AMSR-E) Ka-band passive microwave satellite data. Since its initiation in 2006, the methodology and the GFDS database have been further adapted for data acquired by the Tropical Rainfall Measuring Mission (TRMM) GOES Precipitation Index (GPI), the AMSR2 sensor onboard the Global Change Observation Mission – Water satellite (GCOM-W1), and the Global Precipitation Measurement (GPM) GPM Microwave Imager (GMI) sensor. This paper extends the same flow monitoring methodology to low frequency (L-band) passive microwave observations obtained by the European Space Agency (ESA) Soil Moisture and Ocean Salinity (SMOS) sensor that was launched in 2009. A primary focus is tropical climate regions with dense rainforest vegetation (the Amazon, the Orinoco, and the Congo basins) where high-frequency microwave observations from GFDS reveal a significant influence of vegetation cover and atmospheric humidity. In contrast, SMOS passive microwave signatures at the much lower L-band frequency exhibit deeper penetration through the dense vegetation and minimal atmospheric effects, enabling more robust river stage retrievals in these regions. The SMOS satellite river gauging observations are for 2010–2018 and are compared to single-sensor GFDS data over several river sites. To reduce noise, different filtering techniques were tested to select the one most suitable for analysis of the L-band time series information. In-situ water level (stage) measurements from the French Observation Service SO Hybam database were used for validation to further evaluate the performance of the SMOS data series. In addition to GFDS data, water stage information from Jason-2 and Jason-3 altimetry was compared to the microwave results. Correlation of SMOS gauging time series with in-situ stage data revealed a good agreement (r = 0.8–0.94) during the analyzed period of 2010–2018. Moderate correlation was found with both high frequency GFDS data series and altimetry data series. With lower vegetation attenuation, SMOS signatures exhibited a robust linear relationship with river stage without seasonal bias from the complex hysteresis effects that appeared in the Ka-band observations, apparently due to different attenuation impacts through dense forests at different seasonal vegetation stages.

Published

2019

2. Evaluation of the satellite-based Global Flood Detection System for measuring river discharge: influence of local factors

Author

Peter Salamon, Jutta Thielen, Beatriz Revilla-Romero, G. R. Brakenridge, and T. De Groeve

Subjects

lcsh:GE1-350, Hydrology, geography, geography.geographical_feature_category, Floodplain, lcsh:T, Discharge, Hydrological modelling, lcsh:Geography. Anthropology. Recreation, Vegetation, Land cover, lcsh:Technology, lcsh:TD1-1066, lcsh:G, Environmental science, Satellite, Catchment area, lcsh:Environmental technology. Sanitary engineering, Leaf area index, lcsh:Environmental sciences

Abstract

One of the main challenges for global hydrological modelling is the limited availability of observational data for calibration and model verification. This is particularly the case for real time applications. This problem could potentially be overcome if discharge measurements based on satellite data were sufficiently accurate to substitute for ground-based measurements. The aim of this study is to test the potentials and constraints of the remote sensing signal of the Global Flood Detection System for converting the flood detection signal into river discharge values. The study uses data for 322 river measurement locations in Africa, Asia, Europe, North America and South America. Satellite discharge measurements were calibrated for these sites and a validation analysis with in situ discharge was performed. The locations with very good performance will be used in a future project where satellite discharge measurements are obtained on a daily basis to fill the gaps where real time ground observations are not available. These include several international river locations in Africa: Niger, Volta and Zambezi rivers. Analysis of the potential factors affecting the satellite signal was based on a classification decision tree (Random Forest) and showed that mean discharge, climatic region, land cover and upstream catchment area are the dominant variables which determine good or poor performance of the measurement sites. In general terms, higher skill scores were obtained for locations with one or more of the following characteristics: a river width higher than 1 km; a large floodplain area and in flooded forest; with a potential flooded area greater than 40%; sparse vegetation, croplands or grasslands and closed to open and open forest; Leaf Area Index > 2; tropical climatic area; and without hydraulic infrastructures. Also, locations where river ice cover is seasonally present obtained higher skill scores. The work provides guidance on the best locations and limitations for estimating discharge values from these daily satellite signals.

Published

2014

3. Satellite Remote Sensing and Hydrologic Modeling for Flood Inundation Mapping in Lake Victoria Basin: Implications for Hydrologic Prediction in Ungauged Basins

Author

Fritz Policelli, Jonathan J. Gourley, Robert F. Adler, Dan Irwin, Jiahu Wang, G. R. Brakenridge, Shahid Habib, Koray K. Yilmaz, Yang Hong, and Sadiq Ibrahim Khan

Subjects

Hydrology, Routing (hydrology), Flood myth, Hydrological modelling, Flooding (psychology), General Earth and Planetary Sciences, Moderate-resolution imaging spectroradiometer, Land cover, Electrical and Electronic Engineering, Structural basin, Vflo

Abstract

Floods are among the most catastrophic natural disasters around the globe impacting human lives and infrastructure. Implementation of a flood prediction system can potentially help mitigate flood-induced hazards. Such a system typically requires implementation and calibration of a hydrologic model using in situ observations (i.e., rain and stream gauges). Recently, satellite remote sensing data have emerged as a viable alternative or supplement to in situ observations due to their availability over vast ungauged regions. The focus of this study is to integrate the best available satellite products within a distributed hydrologic model to characterize the spatial extent of flooding and associated hazards over sparsely gauged or ungauged basins. We present a methodology based entirely on satellite remote sensing data to set up and calibrate a hydrologic model, simulate the spatial extent of flooding, and evaluate the probability of detecting inundated areas. A raster-based distributed hydrologic model, Coupled Routing and Excess STorage (CREST), was implemented for the Nzoia basin, a subbasin of Lake Victoria in Africa. Moderate Resolution Imaging Spectroradiometer Terra-based and Advanced Spaceborne Thermal Emission and Reflection Radiometer-based flood inundation maps were produced over the region and used to benchmark the distributed hydrologic model simulations of inundation areas. The analysis showed the value of integrating satellite data such as precipitation, land cover type, topography, and other products along with space-based flood inundation extents as inputs to the distributed hydrologic model. We conclude that the quantification of flooding spatial extent through optical sensors can help to calibrate and evaluate hydrologic models and, hence, potentially improve hydrologic prediction and flood management strategies in ungauged catchments.

Published

2011

4. Orbital SAR remote sensing of a river flood wave

Author

G. R. Brakenridge, B. T. Tracy, and J. C. Knox

Subjects

Hydrology, European Remote-Sensing Satellite, geography, geography.geographical_feature_category, Flood myth, Discharge, Remote sensing (archaeology), Tributary, Overbank, General Earth and Planetary Sciences, Hydrograph, Surface water, Geology

Abstract

During the Great Flood of summer 1993 in the Upper Mississippi Valley, the European Remote Sensing Satellite (ERS-1) imaged overbank flooding with a ground resolution of ca 25 m. When combined with topographic information, these data permit measurement of instantaneous longitudinal profiles of individual flooded valleys. Along a major tributary to the Mississippi in southwestern Wisconsin, a measured in-transit flood wave exhibits an amplitude of 1.5-2.0 m, and can be differentiated from a constant discharge, step backwater-modelled water surface for a distance of 5 km along the valley.

Published

1998