Multiple coherent beam combination systems sharing a common receiver

What is claimed is: 1. A system, comprising: a plurality of beam emitting subsystems for generating and transmitting a plurality of composite output beams toward an area of a target, each beam emitting subsystem configured to generate a plurality of coherent beams for directing towards the area of the target so as to combine at or before the target as a respective one of the composite output beams, wherein for each composite output beam of the plurality of composite output beams a proportion of radiation intensity of the composite output beam is reflected from the area of the target as a reflected radiation component, and wherein the plurality of composite output beams are incoherently combined; a telescope arrangement for collecting radiation reflected from the target and directing the reflected radiation onto a focal plane, the reflected radiation including a plurality of components of radiation, at least some of the components of radiation combining as a combined radiation composed of the reflected radiation components that reflected from the area of the target toward the telescope arrangement, and wherein an intensity of the combined radiation is indicative of radiation intensity of the composite output beams impinging on the target; a spatial filtering configuration deployed at the focal plane and configured for spatially filtering the reflected radiation by passing substantially only the combined radiation composed of the reflected radiation components that reflected from the area of the target toward the telescope arrangement; a radiation distinguishing module for receiving the combined radiation passed by the spatial filtering configuration and for distinguishing, for each reflected radiation component of the combined radiation, an intensity parameter of the reflected radiation component from an intensity parameter of the combined radiation of all other of the reflected radiation components of the combined radiation; and a control subsystem associated with the radiation distinguishing module and each of the beam emitting subsystems, wherein for each reflected radiation component the control subsystem is configured to: receive the intensity parameter of the reflected radiation component from the radiation distinguishing module, and adjust a beam parameter of one or more coherent beams of the composite output beam corresponding to the reflected radiation component based on the received intensity parameter. 2. The system of claim 1 , wherein each beam emitting subsystem includes: a beam generating arrangement for generating the respective one of the composite output beams, and a beam directing arrangement for directing the respective one of the composite output beams towards the target. 3. The system of claim 1 , wherein each reflected radiation component has a different wavelength from all other of the reflected radiation component, and wherein the radiation distinguishing module includes: an optics arrangement including at least one dispersive optical component for separating the combined radiation into a plurality of constituent wavelengths corresponding to the wavelengths of the reflected radiation component, and a detector arrangement for receiving radiation separated by the at least one dispersive optical component, the detector arrangement configured to separately measure radiation at each respective wavelength of the constituent wavelengths. 4. The system of claim 3 , wherein the at least one dispersive optical component includes a prism. 5. The system of claim 3 , wherein the at least one dispersive optical component includes a diffractive grating. 6. The system of claim 3 , wherein the optics arrangement further includes a collimating element deployed in an optical path between the spatial filtering configuration and the at least one dispersive optical component, the collimating element configured for: collimating the combined radiation so as to produce collimated radiation, and directing the collimated radiation to the at least one dispersive optical component. 7. The system of claim 3 , wherein the detector arrangement includes an array of detectors, each respective detector of the array of detectors configured to measure radiation in a different respective wavelength of the constituent wavelengths. 8. The system of claim 1 , wherein each beam emitting subsystem includes: an array of beam sources configured to generate a plurality of coherent beams for directing towards the target so as to combine at or before the target as the respective one of the composite output beams, a plurality of adjustable phase modulators associated with the beams sources so as to allow adjustment of relative phase offsets of the coherent beams, and an encoding module for encoding a phase of each of the coherent beams with a code that is locally unique to the beam emitting subsystem. 9. The system of claim 8 , wherein the radiation distinguishing module includes: a detector deployed to receive the combined radiation and to monitor an intensity parameter of the combined radiation, and a decoding module configured to decode, for each composite output beam, the intensity parameter of the combined radiation according to the locally unique code of the beam emitting subsystem that generated the composite output beam to isolate an intensity parameter of the reflected radiation component corresponding to the composite output beam. 10. The system of claim 9 , wherein the encoding module includes a modulator, and wherein the code includes a modulation frequency such that each composite output beam is assigned at least one unique modulation frequency, and wherein the encoding module is configured to encode the phase of each of the coherent beams for each beam emitting subsystem by modulating the current phase of the coherent beams at the assigned at least one modulation frequency, and wherein the decoding module includes a plurality of demodulators, each demodulator configured to demodulate a signal corresponding to the intensity parameter at one or more selected demodulation frequency selected from the assigned unique modulation frequencies. 11. The system of claim 1 , wherein each beam emitting subsystem includes: an array of beam sources configured to generate a plurality of coherent beams for directing towards the target so as to combine at or before the target as the respective one of the composite output beams, and a plurality of adjustable phase modulators associated with the beams sources so as to allow adjustment of relative phase offsets of the coherent beams. 12. The system of claim 1 , further comprising: an imaging system for generating images of the target, the imaging system including: a wavefront sensor, a deformable mirror for receiving radiation from the spatial filtering configuration, a beam splitter for receiving radiation from the deformable mirror and providing a part of the received radiation to the wavefront sensor and providing another part of the received radiation to the radiation distinguishing module, and an adaptive optics controller associated with the wavefront sensor operative to control the deformable mirror so as to reduce optical distortions in the reflected radiation collected by the telescope arrangement. 13. A system, comprising: a plurality of beam emitting subsystems for generating and transmitting a plurality of composite output beams toward an area of a target, each beam emitting subsystem configured to generate a plurality of coherent beams for directing towards the area of the target so as to combine at or before the target as a respective one of the composite output beams, wherein for each composite outpu