Smart ground-terminal antenna for geostationary satellites in slightly inclined orbits

What is claims is: 1. A method for communication, comprising: providing an antenna system including a reflector having a focus and a feed array positioned at or near the focus and having N feed elements; receiving N feed signals via the N feed elements, the N feed signals resulting from illumination of the N feed elements by a target signal incident on the reflector from a slow-moving signal source; inputting the N feed signals to an N-to-N Fourier Transform device; performing a spatial Fourier Transform on the N feed signals to generate N output signals, via the N-to-N Fourier Transform device; computing a phase slope across the N output signals, via a correlation processor coupled to the N-to-N Fourier Transform device; and determining a direction of arrival of the target signal based on the phase slope, via a direction-of-arrival processor coupled to the correlation processor. 2. The method of claim 1 further comprising: generating a beam weight vector for a beam associated with the direction of arrival; and applying the beam weight vector to the N output signals to generate a receive beam, via a digital beam forming processor. 3. The method of claim 1 , wherein providing the antenna system comprises positioning the N feed elements linearly in a focal plane of the reflector or slightly away from the focus of the reflector. 4. The method of claim 1 , wherein providing the antenna system comprises positioning the N feed elements as a plurality of linear arrays in a focal plane of the reflector or slightly away from the focus of the reflector. 5. The method of claim 1 , wherein providing an antenna system comprises providing the reflector with a parabolic surface or a parabolic-toroidal surface. 6. The method of claim 1 further comprising determining a first feed element of the N feed elements based on the direction of arrival, via the direction-of-arrival processor. 7. The method of claim 6 further comprising selecting a first feed signal of the N feed signals as a receive target signal, the first feed signal being associated with the first feed element, via a switch matrix coupled to the direction-of-arrival processor and the N feed elements. 8. A method for communication, comprising: providing an antenna system including a reflector having a focus and a feed array positioned at or near the focus and having N feed elements; receiving N feed signals via the N feed elements, the N feed signals resulting from illumination of the N feed elements by a set of target signals incident on the reflector from respective slow-moving signal sources; inputting the N feed signals to an N-to-N Fourier Transform device; performing a spatial Fourier Transform on the N feed signals to generate N output signals, via the N-to-N Fourier Transform device; computing cross-correlations from the N output signals to generate a vector modifier, via a correlation processor coupled to the N-to-N Fourier Transform device; computing a phase slope across the N output signals for each of the target signals, via the correlation processor; determining directions of arrival of the respective target signals based on the respective phase slopes, via a direction-of-arrival processor coupled to the correlation processor; and generating, based on the vector modifier and the directions of arrival, beam weight vectors for respective beams associated with the respective directions of arrival, via the direction-of-arrival processor. 9. The method of claim 8 further comprising: applying, via each of digital beam forming processors, a respective one of the beam weight vectors to the N output signals to generate a respective receive beam; and outputting concurrently the respective beams from the respective digital beam forming processors as respective received signals from the slow-moving signal sources. 10. The method of claim 8 , wherein providing the antenna system comprises positioning the N feed elements linearly in a focal plane of the reflector or slightly away from the focus of the reflector. 11. The method of claim 8 , wherein providing the antenna system comprises positioning the N feed elements as a plurality of linear arrays in a focal plane of the reflector or slightly away from the focus of the reflector. 12. The method of claim 8 , wherein providing an antenna system comprises providing the reflector with a parabolic surface or a parabolic-toroidal surface. 13. The method of claim 8 further comprising: inputting time of day and coordinates of a terminal that includes the antenna system to a beam controller; computing second beam weight vectors for a plurality of beam positions and associated null positions based on the time of day and the coordinates of the terminal, via the beam controller; inputting the second beam weight vectors to the direction-of-arrival processor; and generating modified beam weight vectors based on the second beam weight vectors and the vector modifier, via the direction-of-arrival processor. 14. The method of claim 8 , wherein the N-to-N Fourier Transform device includes a Butler Matrix. 15. A method for communication, comprising: providing an antenna system including a reflector having a focus and a feed array positioned at or near the focus and having N feed elements; receiving N feed signals via the N feed elements, the N feed signals resulting from illumination of the N feed elements by a target signal incident on the reflector from a slow-moving signal source; inputting the N feed signals to a first N-to-N Fourier Transform device; performing a spatial Fourier Transform on the N feed signals to generate N output signals, via the first N-to-N Fourier Transform device; computing a phase slope across the N output signals, via a correlation processor coupled to the first N-to-N Fourier Transform device; and determining a direction of arrival of the target signal based on the phase slope, via a direction-of-arrival processor coupled to the correlation processor; generating a beam weight vector for a transmit beam associated with the direction of arrival; and applying the beam weight vector to a transmit signal to generate N element signals, via a digital beam forming processor. 16. The method of claim 15 further comprising: converting the N element signals from digital signals to analog signals via N digital-to-analog converters; frequency up-converting the N analog element signals; and amplifying the N up-converted analog element signals. 17. The method of claim 16 further comprising: inputting the N amplified up-converted analog element signals to a second N-to-N Fourier Transform device; performing a second spatial Fourier Transform on the N amplified up-converted analog element signals to generate N output transmit signals, via the second N-to-N Fourier Transform device; and applying the N output transmit signals to the N feed elements via diplexers. 18. The method of claim 15 , wherein the first and second Fourier Transform devices are respectively first and second Butler Matrices. 19. The method of claim 15 , wherein providing an antenna system comprises providing the reflector with a parabolic surface or a parabolic-toroidal surface. 20. The method of claim 15 , wherein providing the antenna system comprises positioning the N feed elements linearly in a focal plane of the reflector or slightly away from the focus of the reflector.