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Abstract
This study presents a first attempt to estimate the extent and seasonality of northern wetlands using radar altimeter satellite observations. The sensitivity of the Topex‐Poseidon dual‐frequency radar altimeter to detect inundation is investigated and compared with passive and active microwave satellite measurements along with a land surface climatology database. The C band backscatter altimeter signal clearly tracks passive microwave emissivity observations of wetlands and is able to detect small flooded areas. Because of the nadir incidence angle, the radar altimeter also shows more capability to detect wetlands than the C band scatterometer. Monthly flooded areas are calculated by estimating flooded pixel fractional coverage using the altimeter C band backscatter magnitude and a linear mixing model with dual‐frequency altimeter backscatter difference, C–Ku, to account for vegetation effects. Because of the Topex‐Poseidon satellite spatial coverage, the results are given only from 40° N to 66° N. This region nevertheless represents more than 30% of world's inundated surfaces during the summer. A direct validation of the inundated extent is unfortunately impossible on a large scale, due to the scarcity of quantitative observations. As a consequence, the results are evaluated by comparison with other existing estimates. Radar altimetry estimates, comprising natural wetlands and river/lakes, indicate a maximum inundated area of 1.86×106 km2 for July 1993 and 1994 as compared with 1.31×106 km2 from passive microwave technique and ∼2.10×106 km2 from climatology dataset. The wetland seasonal variability derived from the altimeter and passive microwave techniques agrees well. These promising results could soon be applied to the ENVISAT dual‐frequency radar altimeter that will provide a better survey of global inundated surfaces thanks to its much more complete spatial coverage.
Acknowledgments
The authors thank the CTO (Centre de Topographie des Oceans) at the LEGOS (Laboratoire d'Etudes en Géophysique et Océanographie Spatiales, CNES, Toulouse) for providing them with the Topex‐Poseidon radar altimeter data. The authors thank A. Kouraev from the LEGOS for Ob River levels from Topex‐Poseidon. The data can be provided upon request to one of the authors. The ERS‐1 wind‐scatterometer data have been provided by the European Space Agency (ESA).
