We discuss a coherent synthetic aperture radar (SAR) formation whereidentical sensors transmit at the same time, code, and frequency. This is a particular multiple-inputx2013;multiple-output (MIMO) configuration, where the transmitted waveforms interfere together, resulting in an illumination pattern that randomly changes in space and time. Similar to the single-inputx2013;multiple-output (SIMO) formations, the diversity provided by the receiver phase centers can be used to mitigate this interference and reduce the pulse repetition frequency (PRF) for achieving large swath coverage. The good point, in the MIMO case, is that the signal-to-noise ratio (SNR) gain of the system increases, theoretically, with the square of the number of elements. However, residual spurious sidelobes may appear as ghosts of the multiple illuminators. In practice, the power gain is to be optimized, together with ambiguity rejection, sidelobes, and azimuth resolution. The actual performances achievable by these formations in terms of impulse response function (IRF), SNR, and sensitivity to the precise positioning of the sensors are discussed theoretically and based on simulations.
Compact and Free-Floating Satellite MIMO SAR Formations / Giudici, D.; Guccione, P.; Manzoni, M.; Guarnieri, A. M.; Rocca, F.. - In: IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING. - ISSN 1558-0644. - ELETTRONICO. - 60:(2022), pp. 1-12. [10.1109/TGRS.2021.3062973]
Compact and Free-Floating Satellite MIMO SAR Formations
Guccione P.
;
2022-01-01
Abstract
We discuss a coherent synthetic aperture radar (SAR) formation whereidentical sensors transmit at the same time, code, and frequency. This is a particular multiple-inputx2013;multiple-output (MIMO) configuration, where the transmitted waveforms interfere together, resulting in an illumination pattern that randomly changes in space and time. Similar to the single-inputx2013;multiple-output (SIMO) formations, the diversity provided by the receiver phase centers can be used to mitigate this interference and reduce the pulse repetition frequency (PRF) for achieving large swath coverage. The good point, in the MIMO case, is that the signal-to-noise ratio (SNR) gain of the system increases, theoretically, with the square of the number of elements. However, residual spurious sidelobes may appear as ghosts of the multiple illuminators. In practice, the power gain is to be optimized, together with ambiguity rejection, sidelobes, and azimuth resolution. The actual performances achievable by these formations in terms of impulse response function (IRF), SNR, and sensitivity to the precise positioning of the sensors are discussed theoretically and based on simulations.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
