Optical sparse phased array receiver

What is claimed is: 1. A phased array receiver comprising at least first, second and third receiving elements disposed along a row, wherein said second receiving element is disposed between the first and third receiving elements, and wherein a distance between the first and second receiving elements is different than a distance between the second and third receiving elements, said phased array receiver further comprising: first, second and third phase shifters adapted to shift phases of an optical signal received respectively by the first, second and third receiving elements; first, second and third amplitude modulators adapted to modulate amplitudes of the optical signal received by the first, second and third receiving elements; and a combiner adapted to combine the phase-shifted and amplitude-modulated signals supplied by the first, second and third phase shifters and the first, second and third amplitude modulators to generate a combined signal. 2. The sparse optical phased array receiver of claim 1 further comprising: a photo-diode adapted to convert the combined signal to an electrical signal. 3. The sparse optical phased array receiver of claim 1 further comprising: a signal processing block adapted to receive and mix a reference optical signal with the combined signal. 4. The sparse optical phased array receiver of claim 3 further comprising: a phase shifter adapted to shift a phase of the reference optical signal. 5. The sparse optical phased array receiver of claim 4 further comprising: an amplitude modulator adapted to modulate an amplitude of the reference optical signal. 6. A method of detecting a direction of an incident optical signal, the method comprising: receiving the incident optical signal via at least first, second and third receiving elements disposed along a row, wherein said second receiving element is disposed between the first and third receiving elements, and wherein a distance between the first and second receiving elements is different than a distance between the second and third receiving elements; shifting phases of the optical signal received by the first, second and third receiving elements; modulating amplitudes of the optical signal received by the first, second and third receiving elements; and combining the first, second and third phase-shifted and amplitude-modulated optical signals to generate a combined signal. 7. The method of claim 6 further comprising: converting the combined signal to an electrical signal. 8. The method of claim 6 further comprising: mixing a reference optical signal with the combined signal. 9. The method of claim 8 further comprising: shifting a phase of the reference optical signal. 10. The method of claim 9 further comprising: modulating an amplitude of the reference optical signal. 11. A phased array receiver comprising at least first, second and third receiving elements disposed along a two-dimensional array characterized by at least three rows and at least three columns defining nine positions where the at least first, second and third receiving elements may be disposed, wherein the at least first, second and third receiving elements are distributed among the nine positions such at least one of the nine positions does not receive a receiving element, said phased array receiver further comprising: first, second and third phase shifters adapted to shift phases of an optical signal received respectively by the first, second and third receiving elements; first, second and third amplitude modulators adapted to modulate amplitudes of the optical signal received by the first, second and third receiving elements; and a combiner adapted to combine the phase-shifted and amplitude-modulated signals supplied by the first, second and third phase shifters and the first, second and third amplitude modulators to generate a combined signal. 12. The sparse optical phased array receiver of claim 11 further comprising: a photo-diode adapted to convert the combined signal to an electrical signal. 13. The sparse optical phased array receiver of claim 12 further comprising: a signal processing block adapted to receive and mix a reference optical signal with the combined signal. 14. The sparse optical phased array receiver of claim 13 further comprising: a phase shifter adapted to shift a phase of the reference optical signal. 15. The sparse optical phased array receiver of claim 14 further comprising: an amplitude modulator adapted to modulate an amplitude of the reference optical signal. 16. A method of detecting a direction of an incident optical signal, the method comprising: receiving the incident optical signal via at least first, second and third receiving elements disposed along a two-dimensional array characterized by at least three rows and at least three columns defining nine positions where the at least first, second and third receiving elements may be disposed, wherein the at least first, second and third receiving elements are distributed among the nine positions such at least one of the nine positions does not receive a receiving element; shifting phases of the optical signal received by the first, second and third receiving elements; modulating amplitudes of the optical signals received by the first, second and third receiving elements; and combining the first, second and third phase-shifted and amplitude-modulated optical signals to generate a combined signal. 17. The method of claim 16 further comprising: converting the combined signal to an electrical signal. 18. The method of claim 16 further comprising: mixing a reference optical signal with the combined optical signal. 19. The method of claim 18 further comprising: shifting a phase of the reference optical signal. 20. The method of claim 19 further comprising: modulating an amplitude of the reference optical signal. 21. The sparse optical phased array receiver of claim 1 further comprising first, second and third photo-diodes adapted to respectively convert the first, second and third optical signals. 22. The sparse optical phased array receiver of claim 1 further comprising a signal processing block adapted to mix each of the first, second and third optical signals with a reference signal. 23. The method of claim 6 further comprising converting each of the first, second and third optical signals to an electrical signal. 24. The method of claim 6 further comprising: mixing a reference optical signal with the optical signal received by the first, second and third receiving elements. 25. The sparse optical phased array receiver of claim 11 further comprising: first, second and third photo-diodes adapted to respectively convert the optical signal received by the first, second and third receiving elements. 26. The sparse optical phased array receiver of claim 24 further comprising a signal processing block adapted to mix the optical signal received by the first, second and third receiving elements with a reference signal. 27. The sparse optical phased array receiver of claim 1 wherein the at least first, second and third receiving elements are positioned on-grid. 28. The sparse optical phased array receiver of claim 1 wherein the at least first, second and third receiving elements are positioned off-grid. 29. The method of claim 6 wherein t