Speckle reduction in photonic phased arrays

The invention claimed is: 1. An optical phased-array device comprising: an array of phase-controlled elements; a binary-tree optical distribution network configured such that each individual phase-controlled element of the array is located at a leaf in the binary-tree optical distribution network; a M×N coupler positioned at a node of the binary-tree optical distribution network, where M and N are both >1; and two or more optical detectors, each individually coupled to one of two outputs of the M×N coupler; wherein the two or more optical detectors are configured to detect backscattered light received by the phase-controlled elements. 2. The optical phased-array device of claim 1 further comprising: a processor operationally connected to the two or more optical detectors. 3. The optical phased-array device of claim 1 further comprising a local oscillator, wherein said two or more optical detectors are included in a coherent detection arrangement including a splitter, and wherein the local oscillator is operationally connected to the two or more optical detectors via the splitter. 4. The optical phased-array device of claim 1 further comprising a local oscillator, wherein said two or more optical detectors include at least four optical detectors in an in-phase/quadrature (I/Q) detection arrangement including at least one 90 degree hybrid component that provides in-phase and quadrature outputs that have a relative 90 degree phase shift with respect to each other, and wherein the local oscillator is operationally connected to the at least four optical detectors via the 90 degree hybrid component. 5. The optical phased-array device of claim 1 further comprising one or more additional M×N couplers positioned in the binary-tree optical distribution network, where M and N are both >1 for each of the one or more additional M×N couplers; and one or more additional optical detectors each additional optical detector operationally connected to a single port of a single one of the additional M×N couplers. 6. The optical phased-array device of claim 5 further comprising a local oscillator, wherein said two or more optical detectors are included in a coherent detection arrangement including a splitter, and wherein the local oscillator operationally connected to the two or more optical detectors via the splitter. 7. The optical phased-array device of claim 5 further comprising a local oscillator, wherein said two or more optical detectors include at least four optical detectors in an in-phase/quadrature (I/Q) detection arrangement including at least one 90 degree hybrid component that provides in-phase and quadrature outputs that have a relative 90 degree phase shift with respect to each other, and wherein the local oscillator is operationally connected to the at least four optical detectors via the 90 degree hybrid component. 8. The optical phased-array device of claim 5 further comprising a processor operationally connected to all the optical detectors in the optical phased-array device. 9. The optical phased-array device of claim 1 configured such that the fundamental mode of backscattered light is directed to a certain one of the optical detectors and one or more higher order modes of backscattered light are directed to the other of the optical detectors. 10. The optical phased-array device of claim 1 further comprising two additional M×N couplers positioned at a second level of the binary-tree optical distribution network, where M and N are both >1 for each of the two additional M×N couplers, and two additional optical detectors, each optical detector individually coupled to an output of a respective one of the two additional M×N couplers. 11. The optical phased-array device of claim 8 further comprising a local oscillator operatively coupled to all of the optical detectors. 12. The optical phased-array device of claim 10 further comprising a local oscillator, wherein said two or more optical detectors are included in a coherent detection arrangement including a splitter, and wherein the local oscillator is operationally connected to the two or more optical detectors via the splitter. 13. The optical phased-array device of claim 10 further comprising a local oscillator, wherein said two or more optical detectors include at least four optical detectors in an in-phase/quadrature (I/Q) detection arrangement including at least one 90 degree hybrid component that provides in-phase and quadrature outputs that have a relative 90 degree phase shift with respect to each other, and wherein the local oscillator is operationally connected to the at least four optical detectors via the 90 degree hybrid component. 14. The optical phased-array device of claim 10 configured such that only higher order modes of backscattered light are directed to the additional optical detectors. 15. The optical phased-array device of claim 1 wherein the node at which the M×N coupler is positioned is a root of the binary-tree optical distribution network. 16. The optical phased-array device of claim 15 wherein M=2 and N=2 for the M×N coupler. 17. An optical phased-array device comprising: a first array of phase-controlled elements; a first binary-tree optical distribution network configured such that each individual phase-controlled element of the first array is located at a leaf in the first binary-tree optical distribution network; a first M×N coupler positioned at a root of the first binary-tree optical distribution network, where M and N are both >1 for the first M×N coupler; a first pair of two optical detectors, each optical detector individually coupled to one of two outputs of the first M×N coupler; a second array of phase-controlled elements; a second binary-tree optical distribution network configured such that each individual phase-controlled element of the second array is located at a leaf in the second binary-tree optical distribution network; a second M×N coupler positioned at a root of the second binary-tree optical distribution network, where M and N are both >1 for the second M×N coupler; a second pair of two optical detectors, each optical detector individually coupled to one of two outputs of the second M×N coupler; and a local oscillator operatively connected to each individual optical detector of the first and second pairs of optical detectors; wherein the optical detectors are configured to detect backscattered light received by the phase-controlled elements. 18. The optical phased-array device of claim 17 wherein an individual optical detector of the first pair of optical detectors detects one or more odd modes of the backscattered light and an individual optical detector of the second pair of optical detectors detects one or more odd modes of the backscattered light. 19. The optical phased-array device of claim 18 wherein an individual optical detector of the first pair of optical detectors detects one or more even modes of the backscattered light and an individual optical detector of the second pair of optical detectors detects one or more even modes of the backscattered light.