Patent ID: 6072419
Filing Date: 2000-06-06
Classification: G01S

Abstract:
A method for the processing of the reception signal of a Deramp type SAR to obtain a radar image, said Deramp type SAR being placed on board a carrier moving above a region of terrain to be imaged that it illuminates, sending out coherently repeated linear frequency-modulated pulses with a duration T and a modulation slope .alpha., demodulating the echo signal received in return between each transmitted pulse by means of a demodulation ramp that is centered in range on the middle of the useful illuminated zone or useful swath, resumes the form of all or part of the transmitted pulse and has a duration T.sub.d smaller than or equal to the duration T of a transmitted pulse, sufficient to cover the reception time interval where the echo signals of all the targets of the useful swath overlap and, after demodulation, delivering an unprocessed video reception signal available in the form of successive samples or reception data elements that are taken at a double rate: a fast rate corresponding to the sequence of range gates and defining a temporal dimension of range .tau. along a range axis oriented laterally to the path of the carrier of the SAR and a slow rate corresponding to the succession of recurrences and defining a temporal dimension of azimuth t along an azimuth axis oriented in the direction of shift of the carrier of the SAR, these samples or data elements taking the form of a table of reception data with two dimensions, range and azimuth, wherein this method comprises the following successive processing steps:the passage of the data elements from the reception data table into a dispersive delay line with a pulse response h.sub.l (t) such that its instantaneous frequency is a linear function of the time: ##EQU62## with a linear modulation slope having a frequency K chosen to be equal to: ##EQU63## T.sub.a being the useful duration of demodulation or duration of a common temporal support chosen for the demodulation of the echo signals coming from all the targets of the useful swath, this useful duration T.sub.a being smaller than or equal to the duration T.sub.d of the demodulation ramp and greater than or equal to the period of time beginning before the start of reception of an echo sent back by a target placed in distance at the far end of the useful swath and ending after the end of reception of an echo sent by a target placed in distance at the near end of the useful swath while at the same time being centered in distance on the middle of the useful swath,the selection, from among the data elements of the 2D table, of reception data elements, consisting of the withdrawal of the reception data elements arriving along the range axis outside the useful duration chosen T.sub.a and their replacement by zero values,the replacement of the data elements of the table of reception data, considered in the range dimension, by their Fourier transform, which is one-dimensional in range, for the obtaining, after demodulation and passage through the dispersive line, of a type of pulse compression to which there is assigned a parasitic phase term of pulse compression,the rearrangement of the data elements of the table in the range dimension in order to have available data corresponding to an order of moving away that increases in range,the subdivision of the table into overlapping bands, parallel to the azimuth axis, so as to have bands corresponding to narrow zones of range .tau..sub.i where it is possible, as a function of the geometrical parameters of the image taken, to locally determine a image focusing 2D filter having a pulse response h(.tau.,t,.tau..sub.i) with two temporal variables, namely .tau. range and t azimuth, and a function of correction of the parasitic phase due to the pulse compression, that are stationary in the range band .tau..sub.i,the filtering of the table bands by the image focusing 2D filter whose pulse response has been modified by the parasitic phase correction function,the juxtaposition of the table bands resulting from the filtering to obtain a table of complex reflection coefficients of the points of the illuminated region of ground, andthe construction of an image of the illuminated region from the moduli of the complex reflection coefficients represented in the table obtained in the previous step.