Assessing optical earth observation systems for mapping and monitoring temporary ponds in arid areas

Soti, Valérie; Tran, Annelise; Bailly, Jean-Stéphane; Puech, Christian; Seen, Danny Lo; Bégué, Agnès

doi:10.1016/j.jag.2009.05.005

Cited by 71 publications

(69 citation statements)

References 17 publications

(23 reference statements)

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“…Generally, the limits of these ponds are delineated by a belt of trees which corresponds to the maximum water extension. Most of the ponds in the study area are small (33% of ponds with an area less than 1000 m 2 and 64% with less than 2600 m 2 ), with the smallest one covering only 74 m 2 and the largest one, Barkedji, covering ∼347 400 m 2 (Soti et al, 2009). The larger ponds are located in the main stream of the Ferlo valley and the smaller ones generally outside.…”

Section: Study Areamentioning

confidence: 99%

“…In arid areas, the potential of time series from coarse-scale satellites images like NOAA-AVHRR (Verdin, 1996), SPOT-Vegetation (Haas et al, 2006) or Terra-MODIS (Moderate Resolution Imaging Spectroradiometer) to survey large ponds and lakes at a broad spatial scale was demonstrated. Nevertheless, in the Sahel region, the spatial resolution of those sensors is inappropriate (Soti et al, 2009) for identifying water bodies with a surface area of less than 170 000 m 2 (Soti et al, 2009), which is the case for most of the ponds there. Recently, it was shown that the new generation of high and very high spatial resolution remote sensing data (Landsat Enhanced Thematic Mapper, SPOT5 and Quickbird images) is suitable for the detailed mapping of temporary water bodies at a local scale (Liebe et al, 2005;Lacaux et al, 2007;Soti et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, in the Sahel region, the spatial resolution of those sensors is inappropriate (Soti et al, 2009) for identifying water bodies with a surface area of less than 170 000 m 2 (Soti et al, 2009), which is the case for most of the ponds there. Recently, it was shown that the new generation of high and very high spatial resolution remote sensing data (Landsat Enhanced Thematic Mapper, SPOT5 and Quickbird images) is suitable for the detailed mapping of temporary water bodies at a local scale (Liebe et al, 2005;Lacaux et al, 2007;Soti et al, 2009). The potential of radar satellite images (Annor et al, 2009;Di Baldassarre et al, 2009;) for water body inventory have also been improved, with the advantage of being independent of cloud cover (Horritt et al, 2001;Herold et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

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The potential for remote sensing and hydrologic modelling to assess the spatio-temporal dynamics of ponds in the Ferlo Region (Senegal)

Soti

Puech²,

Seen

et al. 2010

Hydrol. Earth Syst. Sci.

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Abstract. In the Ferlo Region in Senegal, livestock depend on temporary ponds for water but are exposed to the Rift Valley Fever (RVF), a disease transmitted to herds by mosquitoes which develop in these ponds. Mosquito abundance is related to the emptying and filling phases of the ponds, and in order to study the epidemiology of RVF, pond modelling is required. In the context of a data scarce region, a simple hydrologic model which makes use of remote sensing data was developed to simulate pond water dynamics from daily rainfall. Two sets of ponds were considered: those located in the main stream of the Ferlo Valley whose hydrological dynamics are essentially due to runoff, and the ponds located outside, which are smaller and whose filling mechanisms are mainly due to direct rainfall. Separate calibrations and validations were made for each set of ponds. Calibration was performed from daily field data (rainfall, water level) collected during the 2001 and 2002 rainy seasons and from three different sources of remote sensing data: 1) very high spatial resolution optical satellite images to access pond location and surface area at given dates, 2) Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) Digital Elevation Model (DEM) data to estimate pond catchment Correspondence to: V. Soti (vs.nev@ntropic.fr) area and 3) Tropical Rainfall Measuring Mission (TRMM) data for rainfall estimates. The model was applied to all ponds of the study area, the results were validated and a sensitivity analysis was performed. Water height simulations using gauge rainfall as input were compared to water level measurements from four ponds and Nash coefficients >0.7 were obtained. Comparison with simulations using TRMM rainfall data gave mixed results, with poor water height simulations for the year 2001 and good estimations for the year 2002. A pond map derived from a Quickbird satellite image was used to assess model accuracy for simulating pond water areas for all the ponds of the study area. The validation showed that modelled water areas were mostly underestimated but significantly correlated, particularly for the larger ponds. The results of the sensitivity analysis showed that parameters relative to pond shape and catchment area estimation have less effects on model simulation than parameters relative to soil properties (rainfall threshold causing runoff in dry soils and the coefficient expressing soil moisture decrease with time) or the water loss coefficient. Overall, our results demonstrate the possibility of using a simple hydrologic model with remote sensing data to track pond water heights and water areas in a homogeneous arid area.

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Section: Study Areamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The potential for remote sensing and hydrologic modelling to assess the spatio-temporal dynamics of ponds in the Ferlo Region (Senegal)

Soti

Puech²,

Seen

et al. 2010

Hydrol. Earth Syst. Sci.

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“…vegetation or water, to enhance classification results. Based on information gathered from other studies on water bodies (Lillesand et al, 2004;Soti et al, 2009Soti et al, , 2010Wolf, 2010), the following indices were created and explored in view of SWB delineation: the normalised difference water index (NDWI) = (coastal blue -NIR2) / (coastal blue + NIR2), the standing water index (SWI) = (blue -NIR1)/(blue + NIR1) and the normalized difference vegetation index (NDVI) = (NIR1 -red) / NIR1 + red). These indices, together with the hue (red, green, blue) transformation, were incorporated in the analysis.…”

Section: Indices and Ratiosmentioning

confidence: 99%

“…spatial resolution of <5 m, has made it possible to acquire spatial accuracy at sub-meter scales thereby allowing the detection of water bodies that cover only a few m 2 . However, few initiatives have been undertaken to monitor SWBs using VHR satellite imagery (Dambach et al, 2009;Soti et al, 2009;Soti et al, 2010). Many studies use the freely available Landsat imagery (about 30-m resolution) and medium (20 m to 100 m) or coarse (>100 m) resolution imagery (Fuentes et al, 2001;Malone et al, 2001;Guo et al, 2005;Daniel et al, 2006;de Castro et al, 2006;Estallo et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Fine-scale mapping of vector habitats using very high resolution satellite imagery: a liver fluke case-study

et al. 2014

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Abstract. The visualization of vector occurrence in space and time is an important aspect of studying vector-borne diseases. Detailed maps of possible vector habitats provide valuable information for the prediction of infection risk zones but are currently lacking for most parts of the world. Nonetheless, monitoring vector habitats from the finest scales up to farm level is of key importance to refine currently existing broad-scale infection risk models. Using Fasciola hepatica, a parasite liver fluke as a case in point, this study illustrates the potential of very high resolution (VHR) optical satellite imagery to efficiently and semi-automatically detect detailed vector habitats. A WorldView2 satellite image capable of <5m resolution was acquired in the spring of 2013 for the area around Bruges, Belgium, a region where dairy farms suffer from liver fluke infections transmitted by freshwater snails. The vector thrives in small water bodies (SWBs), such as ponds, ditches and other humid areas consisting of open water, aquatic vegetation and/or inundated grass. These water bodies can be as small as a few m 2 and are most often not present on existing land cover maps because of their small size. We present a classification procedure based on object-based image analysis (OBIA) that proved valuable to detect SWBs at a fine scale in an operational and semi-automated way. The classification results were compared to field and other reference data such as existing broad-scale maps and expert knowledge. Overall, the SWB detection accuracy reached up to 87%. The resulting fine-scale SWB map can be used as input for spatial distribution modelling of the liver fluke snail vector to enable development of improved infection risk mapping and management advice adapted to specific, local farm situations.

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Exploring Ecology and Associated Disease Pattern

Bhunia

Shit²

2018

Geospatial Analysis of Public Health

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Assessing optical earth observation systems for mapping and monitoring temporary ponds in arid areas

Cited by 71 publications

References 17 publications

The potential for remote sensing and hydrologic modelling to assess the spatio-temporal dynamics of ponds in the Ferlo Region (Senegal)

The potential for remote sensing and hydrologic modelling to assess the spatio-temporal dynamics of ponds in the Ferlo Region (Senegal)

Fine-scale mapping of vector habitats using very high resolution satellite imagery: a liver fluke case-study

Exploring Ecology and Associated Disease Pattern

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