Title :
Stabilized image reconstruction algorithm for synthetic aperture imaging radiometers
Author_Institution :
Signal & Image Process. Group, CERFACS, Toulouse, France
Abstract :
It is now well established that synthetic aperture imaging radiometers promise to be powerful sensors for high-resolution observations of the Earth at low microwave frequencies. Within this context, the European Space Agency (ESA) is currently developing the SMOS (Soil Moisture and Ocean Salinity) mission. The Y-shaped array selected for SMOS is fitted with equally spaced antennae and leads to natural hexagonal sampling grids. This article deals with the reconstruction of radiometric brightness temperature maps over such grids from interferometer measurements. The corresponding inverse problem is stated without any reference to the numerical method that could be used to solve it. To support the theory, numerical simulations are presented and analyzed with emphasis on stability and error analysis.
Keywords :
electromagnetic wave interferometry; image reconstruction; radiometers; Earth; SMOS mission; Soil Moisture and Ocean Salinity; Y-shaped array; equally spaced antennae; error analysis; hexagonal sampling grids; high-resolution observations; interferometer measurements; interferometry; inverse problem; microwave frequencies; numerical simulations; radiometric brightness temperature maps; radiometry; stability analysis; stabilized image reconstruction algorithm; synthetic aperture imaging radiometers; Earth; High-resolution imaging; Image reconstruction; Image sensors; Microwave frequencies; Microwave imaging; Microwave sensors; Radiometers; SMOS mission; Space missions;
Conference_Titel :
Geoscience and Remote Sensing Symposium, 2002. IGARSS '02. 2002 IEEE International
Print_ISBN :
0-7803-7536-X
DOI :
10.1109/IGARSS.2002.1026207
