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Free-space optical communication uses multibeam communications, for example between a base station and multiple remote stations. To improve efficiency and reduce complexity, the base station transmitter utilizes a single wide-angle objective lens for all of the optical beams' radiation sources. The

Free-space optical communication uses multibeam communications, for example between a base station and multiple remote stations. To improve efficiency and reduce complexity, the base station transmitter utilizes a single wide-angle objective lens for all of the optical beams' radiation sources. The optical radiation sources are provided with fiberoptic transmitting pigtails with output ends installed on a curved surface in relation to the single wide-angle objective lens at locations in the areas optically conjugated with the remote subscriber receivers. In a system for two-way communication, optical receivers are provided with fiberoptic receiving pigtails with input ends positioned on the curved surface at locations relative to the wide-angle objective lens, which are optically conjugated with the remote subscriber radiation sources. In the preferred embodiments, the mountings of the output and input ends of the transmitting and the receiving pigtails enable their movement along the curved surface as well as along an optical beam axis. Also, a preferred embodiment of the optical system enables movement of the wide angle objective lens together with the output and input ends of the transmitting and the receiving pigtails about horizontal and vertical axes.

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1. An optical communication system comprising:a plurality of remote subscriber receivers with optical demodulation means; andan optical base terminal comprising:a transmitter implemented as a plurality of base terminal optical radiation sources driven by associated modulators, the base terminal opti

1. An optical communication system comprising:a plurality of remote subscriber receivers with optical demodulation means; andan optical base terminal comprising:a transmitter implemented as a plurality of base terminal optical radiation sources driven by associated modulators, the base terminal optical radiation sources provided with fiberoptic transmitting pigtails, where output ends of the pigtails are positioned on a curved surface; anda single wide-angle objective lens located between the output ends of the transmitting pigtails and paths to the remote subscriber receivers,wherein the output ends of the transmitting pigtails are positioned on the curved surface in areas optically conjugated with the remote subscriber receivers relative to the wide-angle objective lens. 2. A system as in claim 1, further comprising a mounting supporting the output end of each transmitting pigtail on the curved surface enabling movement along the curved surface and along an axis of a respective radiated optical beam. 3. A system as in claim 1, further comprising:a plurality of remote subscriber radiation sources with optical modulation means; andbase terminal receivers provided with fiberoptic receiving pigtails,wherein input ends of the receiving pigtails are located on the curved surface and optically conjugated with the subscriber radiation sources relative to the wide-angle objective lens. 4. A system as in claim 3, further comprising a mounting supporting the input end of each receiving pigtail enabling movement along the curved surface and along an axis of a respective received radiation beam. 5. A system as in claim 4, further comprising a mounting structure supporting the objective lens so that it can be rotated together with the output and ends of the transmitting pigtails and the input ends of the receiving pigtails, relative to an arbitrary axis. 6. A system as in claim 1, wherein the wide angle objective lens comprises concentric lens and axes of the fiberoptic pigtails are targeted substantially at the lens center. 7. A system as in claim 6, wherein the concentric lens is a spherical lens. 8. An optical device for multibeam communication of a base terminal to and from a plurality of remote terminals, the optical device comprising:a plurality of optical radiation sources provided with fiberoptic transmitting pigtails with output ends positioned on a curved surface;a plurality of optical radiation receivers provided with fiberoptic receiving pigtails with input ends positioned on the curved surface; anda single wide-angle objective lens located between paths for the remote terminals and the output and input ends of the transmitting pigtails and the receiving pigtails respectively, wherein:the output ends of the transmitting pigtails are positioned on the curved surface in areas optically conjugated with receivers of respective remote terminals relative to the wide-angle objective lens, andthe input ends of the receiving pigtails are positioned on the curved surface in areas optically conjugated with radiation sources of respective remote terminals relative to the wide-angle objective lens. 9. A device as in claim 8, further comprising:a mounting supporting the output end of each transmitting pigtail on the curved surface enabling movement along the curved surface and along an axis of a respective radiated optical beam; anda mounting supporting the input end of each receiving pigtail enabling movement along the curved surface and along an axis of a respective received radiation beam. 10. A device as in claim 8, further comprising a mounting structure supporting the objective lens so that it can be rotated together with the output and input ends of the transmitting pigtails and the receiving pigtails respectively, relative to at least one arbitrary axis. 11. A device as in claim 8, wherein the wide angle objective lens comprises concentric lens and the axes of the transmitting and receiving fiberoptic pigtails are targeted substant ially at the lens center. 12. A device as in claim 11, wherein the concentric lens is a spherical lens. 13. An optical device for multibeam communication of a base terminal to a plurality of remote terminals, the optical device comprising:a plurality of optical radiation sources provided with fiberoptic transmitting pigtails with output ends positioned on a curved surface; anda single wide-angle objective lens located between paths to the remote terminals and the output ends of the transmitting pigtails, wherein:the output ends of the transmitting pigtails are positioned on the curved surface in areas optically conjugated with receivers of respective remote terminals relative to the wide-angle objective lens. 14. A device as in claim 13, further comprising a mounting supporting the output end of each transmitting pigtail on the curved surface enabling movement along the curved surface and along an axis of a respective radiated optical beam. 15. A device as in claim 13, further comprising a mounting structure supporting the objective lens so that it can be rotated together with the output ends of the transmitting pigtails, relative to at least one arbitrary axis. 16. A device as in claim 13, further comprising an adjustable mirror and a pair of adjustment optical wedges for each path to a respective receiver of a remote terminal mounted in proximity to the objective lens along the path to the respective receiver. 17. A device as in claim 13, wherein the wide angle objective lens comprises concentric lens and axes of fiberoptic pigtails are targeted substantially at the lens center. 18. A device as in claim 17, wherein the wide angle objective lens comprises a spherical lens. 19. An optical device for receiving multibeam communication for a base terminal from a plurality of remote terminals, the optical device comprising:a plurality of optical radiation receivers provided with fiberoptic receiving pigtails having input ends positioned on a curved surface; anda single wide-angle objective lens located between paths from the remote terminals and the input ends of the receiving pigtails, wherein:the input ends of the receiving pigtails are positioned on the curved surface in areas optically conjugated with radiation sources of respective remote terminals relative to the wide-angle objective lens. 20. A device as in claim 19, further comprising a mounting supporting each radiation receiver enabling movement along the curved surface and along an axis of a respective received radiation beam. 21. A device as in claim 19, further comprising a mounting structure supporting the objective lens so that it can be rotated together with the input ends of the receiving pigtails, relative to at least one arbitrary axis. 22. A device as in claim 19, wherein the wide angle objective lens comprises a concentric lens, and axes of the fiberoptic pigtails are targeted substantially at the lens center. 23. A device as in claim 22, wherein the concentric lens comprises a spherical lens. 24. An optical communication system comprising:a plurality of remote subscriber receivers with optical demodulation means; andan optical base terminal comprising:a transmitter implemented as a plurality of base terminal optical radiation sources driven by associated modulators;a mounting supporting each of the base terminal radiation sources on a curved surface, enabling movement along the curved surface and along an axis of a respective radiated optical beam; anda single wide-angle objective lens located between the radiation sources and paths to the remote subscriber receivers,wherein the base terminal radiation sources are positioned on the curved surface in areas optically conjugated with the remote subscriber receivers relative to the wide-angle objective lens. 25. An optical communication system comprising:a plurality of remote subscriber receivers with optical demodulation means;a plurality of remote subscriber radiation sources with optical modulation means; anda n optical base terminal comprising:a transmitter implemented as a plurality of base terminal optical radiation sources driven by associated modulators;a single wide-angle objective lens located between the radiation sources and paths to the remote subscriber receivers, the base terminal radiation sources being positioned on a curved surface in areas optically conjugated with the remote subscriber receivers relative to the wide-angle objective lens;base terminal receivers located on the curved surface and optically conjugated with the subscriber radiation sources relative to the wide-angle objective lens; anda mounting supporting each base terminal receiver enabling movement along the curved surface and along an axis of a respective received radiation beam. 26. A system as in claim 25, further comprising a mounting structure supporting the objective lens so that it can be rotated together with the base terminal radiation sources and the base terminal receivers, relative to an arbitrary axis. 27. An optical device for multibeam communication of a base terminal to and from a plurality of remote terminals, the optical device comprising:a plurality of optical radiation sources positioned on a curved surface;a plurality of optical radiation receivers positioned on the curved surface;a single wide-angle objective lens located between paths for the remote terminals and the radiation sources and receivers, wherein:the radiation sources are positioned on the curved surface in areas optically conjugated with receivers of respective remote terminals relative to the wide-angle objective lens, andthe radiation receivers are positioned on the curved surface in areas optically conjugated with radiation sources of respective remote terminals relative to the wide-angle objective lens;a mounting supporting each radiation source on the curved surface enabling movement along the curved surface and along an axis of a respective radiated optical beam; anda mounting supporting each radiation receiver enabling movement along the curved surface and along an axis of a respective received radiation beam. 28. An optical device for multibeam communication of a base terminal to a plurality of remote terminals, the optical device comprising:a plurality of optical radiation sources; anda mounting supporting each radiation source on a curved surface enabling movement along the curved surface and along an axis of a respective radiated optical beam; anda single wide-angle objective lens located between paths to the remote terminals and the radiation sources, wherein the radiation sources are positioned on the curved surface in areas optically conjugated with receivers of respective remote terminals relative to the wide-angle objective lens. 29. An optical device for receiving multibeam communication for a base terminal from a plurality of remote terminals, the optical device comprising:a plurality of optical radiation receivers;a mounting supporting each radiation receiver on a curved surface and enabling movement along the curved surface and along an axis of a respective received radiation beam; anda single wide-angle objective lens located between paths from the remote terminals and the radiation receivers, wherein the radiation receivers are positioned on the curved surface in areas optically conjugated with radiation sources of respective remote terminals relative to the wide-angle objective lens.