Abstract
In recent years, an increasing interest has been devoted to bistatic SAR configurations, which can be effectively used to improve system performance and/or to increase the amount of physical information retrievable from the observed scene. Within this context, the availability of simulation tools is of paramount importance, for both mission planning and processing algorithm verification and testing. In this paper, a time domain simulator useful to obtain the point-spread function and the raw signal for the generic bistatic SAR configuration is presented. Moreover, we focus on the case of two bistatic configurations, which are of considerable interest in actual SAR applications, i.e., the translational invariant SAR and the one-stationary SAR acquisition geometries, for which we obtain meaningful expressions of the Transfer Functions. In particular, these expressions are formally equal to those obtained for the monostatic SAR configuration, so that the already available monostatic simulator can be easily adapted to these bistatic cases. The point-target raw signals obtained using the (exact) time domain simulator and the (approximated) frequency domain one are compared, with special attention to acquisition geometries that may be of practical interest in Formation-Flying SAR applications. Results show that the phase difference between raw signals simulated with the two approaches is, in all cases, smaller (and often much smaller) than about 10 degrees, except that at the very edge of the raw signals, where however, it does not exceed about 50 degrees.
Highlights
Until now, Synthetic Aperture Radar (SAR) missions have been designed mostly to work in monostatic configuration
This Section is devoted to illustrating the results of numerical simulations relevant to the two bistatic SAR configurations described in Sections 3.1 and 3.2
Presented raw signals lie in the slow-time/fast-time plane; the slow-time duration of each raw signal corresponds to the time slot within which the look function is equal to 1, while its fast-time duration is the difference between the maximum and the minimum round trip of the transmitted pulse increased by the pulse duration
Summary
Synthetic Aperture Radar (SAR) missions have been designed mostly to work in monostatic configuration. Most of them consider specific acquisition geometries, such as the translational invariant (TI) [21,22], where the transmitter and the receiver share the same velocity vector (i.e., they move along parallel orbits with the same velocity), and the one-stationary bistatic configuration [24], where the receiver is fixed and placed close to the Earth surface In these special cases, simplified formulations of the system impulse response and transfer function (TF) can be obtained and, computationally efficient processing schemes can be devised. We present a SAR simulator working in the time domain (TD) able to obtain the point-spread function (PSF) and the raw signal for generic bistatic configurations This is accomplished defining an appropriate look function of the bistatic system, i.e., the function describing the time interval in which a point target is simultaneously seen from both the transmitter and the receiver.
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