Radar altimetry provides unique information on water stages of inland hydro-systems. In this study, the performance of seven altimetry missions, among the most commonly used in land hydrology (i.e., European Remote-Sensing Satellite-2 (ERS-2), ENVIronment SATellite (ENVISAT), Satellite with Argos and ALtika (SARAL), Jason-1, Jason-2, Jason-3 and Sentinel-3A), are assessed using records from a dense in situ network composed of 19 gauge stations in the Inner Niger Delta (IND) from 1995 to 2017. Results show an overall very good agreement between altimetry-based and in situ water levels with correlation coefficient (R) greater than 0.8 in 80% of the cases and Root Mean Square Error (RMSE) lower than 0.4 m in 48% of cases. Better agreement is found for the recently launched missions such as SARAL, Jason-3 and Sentinel-3A than for former missions, indicating the advance of the use of the Ka-band for SARAL and of the Synthetic-aperture Radar (SAR) mode for Sentinel-3A. Cross-correlation analysis performed between water levels from the same altimetry mission leads to time-lags between the upstream and the downstream part of the Inner Niger Delta of around two months that can be related to the time residence of water in the drainage area.
International audienceThis study presents a comprehensive comparison of radar altimetry signatures at Ka-, Ku-, C-, and S-bands using SARAL, ENVISAT and Jason-2 data over the major bioclimatic zones, soil and vegetation types encountered in West-Africa, with an emphasis on the new information at Ka-band provided by the recently launched SARAL–Altika mission. Spatio-temporal variations of the radar altimetry responses were related to changes in surface roughness, land cover and soil wetness. Analysis of time series of backscattering coefficients along the West African bioclimatic gradient shows that radar echoes at nadir incidence are well correlated to soil moisture in semi-arid savannah environments. Radar altimeters are able to detect the presence of water even under a dense canopy cover at all frequencies. But only measurements at Ka-band are able to penetrate underneath the canopy of non-inundated tropical evergreen forests
Abstract. The comprehension of water level fluctuations and the
sustainability of the Inner Niger River Delta (IND) is a major concern for
the scientific community, but also for the local population. Located in the
centre of Mali, the heart of the Sahel, the delta is characterised by a
floodable area of more than 32 000 km2 during the rainy season, which
contributes very strongly to the vitality of local ecosystem, and is
consequently classified as a Ramsar site under the international Convention
for Wetlands. In addition, the Delta acts as an environmental and
socio-economic development barometer for the entire sub-region. Nowadays, we
can observe an increasing fragility of the delta due to climate change,
desertification and human activities, and justifies the need for permanent
monitoring. The present study is based on the recent successes of radar
altimetry, originally designed to monitor the dynamics topography of the
ocean, and now very frequently used to retrieve inland water levels, of
lakes, rivers, and wetlands. Previous studies evaluated the performances of
several radar altimetry missions including Low Resolution Mode (LRM)
(Topex-Poseidon, Jason-1/2/3, ERS-2, ENVISAT, and SARAL, and Synthetic
Aperture Radar (SAR) Sentinel-3A missions for water level retrievals over
1992–2017. More than 50 times series of water levels were build at the
crossing between water bodies and Sentinel-3A and 3B over 2016–2020.
Twenty-four comparisons between in-situ and altimetry-based time-series of
water levels were achieved over the IND. RMSE generally lower than 0.7 m and
r higher than 0.9 were obtained.
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