Author_Institution :
Aerospace Group, Thomson-CSF, Paris, France
Abstract :
The beam agility of phased arrays eases fast time sharing between search, acquisition and tracking modes for radars in a varying environment. For ground or surface applications requiring full azimuth coverage, Thomson-CSF designers chose rotating antennas instead of multi-faceted ones. Innovative designs, such as the RADANT prism, have been developed for the to-day phased arrays. To achieve high reliability and improved performance, active arrays are developed, using solid state T/R modules. Furthermore, by processing digitally the transmitted signals and/or the received ones, such arrays permit space/time signal processing for better parasitic signal cancellation, target resolution and non-cooperative recognition. These present and future technologies are illustrated by existing equipment (ARABEL, FLAIR, RBE2) and ongoing developments (RIAS), two of them conducted on an international basis (COBRA, AMSAR)
Keywords :
active antenna arrays; adaptive signal processing; antenna phased arrays; military systems; phased array radar; radar antennas; radar signal processing; radar target recognition; radar tracking; signal resolution; AMSAR; ARABEL; COBRA; FLAIR; France; RADANT prism; RBE2; RIAS; Thomson-CSF; acquisition mode; active arrays; azimuth coverage; beam agility; digital signal processing; noncooperative recognition; parasitic signal cancellation; phased array radar; phased arrays; radar tracking; received signals; rotating antennas; solid state T/R modules; space/time signal processing; target resolution; tracking mode; transmitted signals; Array signal processing; Azimuth; Phased arrays; Radar antennas; Radar tracking; Signal processing; Signal resolution; Solid state circuits; Space technology; Time sharing computer systems;
