Ender, J.J.EnderCerutti-Maori, D.D.Cerutti-Maori2022-03-102022-03-102006https://publica.fraunhofer.de/handle/publica/353796Ground moving target indication (GMTI) by a space-based radar system can be obtained by a multi-subaperture / multichannel radar system or a satellite cluster. The simplest approach with the receiving antenna split into two halves - and most popular in the SAR community - is to use the technique of along-track interferometry (ATI) to recognize moving objects. Caused by the ambiguity between radial velocity and azimuth position, the SAR processor images the moving object at a wrong position. Re-positioning can be performed by the exploitation of the interferometric phase; but, if the clutter contribution from the affected resolution cell is not negligible compared to the signal power, a severe estimation error will result. A larger number of subapertures permits a better performance using space-time adaptive processing (STAP), but a larger number of receive channels is not attractive for space-based systems because of weight, power consumption and data rate. Nevertheless, since phased array antennas offer the possibility to switch the phases and amplitudes of the T/R modules from pulse to pulse within each subaperture, additional degrees of freedom can be introduced increasing the performance considerably. In this paper, space-based multi-aperture radar systems will be analysed with respect to the relocation error, including time-multiplexed aperture switching techniques. Moreover, an azimuth estimation algorithm for this mode is investigated.en621conference paper