System and method for focal-plane illuminator/detector (FASID) design for improved graded index lenses

What is claimed is: 1. A detector system for imaging an optical signal received by a graded index (GRIN) optical element to account for known variations in a graded index distribution of the GRIN optical element, the detector system comprising: a plurality of optical detector elements configured to receive optical rays received by the GRIN optical element at a plurality of specific locations on a plane, where the plane forms a part of the GRIN optical element or is downstream of the GRIN optical element relative to a direction of propagation of the optical rays; ray tracing software configured to receive and map the optical rays to a plurality of additional specific locations on the plane based on the known variations in the graded index distribution of the GRIN optical element; and a processor, including algorithms for diagonalization of a linear system matrix, configured to determine information on both an intensity and an angle of the received optical rays at each one of the plurality of specific locations on the plane. 2. The detector system of claim 1 , wherein the system is configured to use the information on both the intensity and an angle of received optical rays at each one of the plurality of specific locations on the plane to generate a correction for at least one of the angle and intensity to account for the variation in the graded index of the GRIN optical element. 3. The detector system of claim 2 , further comprising a memory in communication with the processor, the memory including algorithms for diagonalization of a linear system matrix which use the information on both the intensity and the angle of received optical rays at each one of the plurality of specific locations on the plane to generate a correction for at least one of the angle and intensity to account for the variation in the graded index of the GRIN optical element. 4. The detector system of claim 1 , wherein the plurality of optical detector elements comprises a plurality of lenslets. 5. The detector system of claim 4 , wherein the plurality of lenslets comprises a plurality of lenslets sufficient in number and arranged to cover an entire area of the plane. 6. The detector system of claim 5 , wherein each one of the plurality of lenslets receives signals from a plurality of associated pixels. 7. The detector system of claim 6 , wherein the plurality of associated pixels receive the optical rays. 8. The detector system of claim 4 , wherein the optical rays are received at an input surface of the GRIN optical element, and wherein the lenslets are arranged on or adjacent an output surface of the GRIN optical element, the output surface forming the plane. 9. The detector system of claim 1 , wherein the ray tracing software traces received optical rays to specific locations on an input surface of the GRIN optical element, to thus map optical rays received at the input surface of the GRIN optical element to tan output surface of the GRIN optical element, the output surface forming the plane of the GRIN optical element. 10. A detector system for imaging an optical signal received by a graded index (GRIN) optical element to account for known variations in a graded index distribution of the GRIN optical element, the detector system comprising: a plurality of lenslets forming detector elements for receiving optical rays received by the GRIN optical element at a plurality of locations on a focal plane of the GRIN optical element; ray tracing software configured to map the received optical rays to a plurality of different, specific locations on the focal plane of the GRIN optical element based on the known variations in the graded index distribution of the GRIN optical element; a processor configured to: calculate a distribution of both an intensity and an angle of the received optical rays at each one of the plurality of specific locations on the focal plane of the GRIN optical element; and to modify both the intensity and angle of the received optical rays, based on the calculated distribution of the intensity and angle of the received optical rays, to account for the known variations in the graded index distribution of the GRIN optical element. 11. The detector system of claim 10 , wherein the plurality of lenslets are sufficient in number and arranged to cover an entire area of the focal plane. 12. The detector system of claim 11 , wherein each one of the plurality of lenslets receives signals from an associated plurality of pixels. 13. The detector system of claim 12 , wherein each said associated plurality of pixels is configured to receive the optical rays. 14. The detector system of claim 10 , wherein the ray tracing software traces received optical rays to specific locations on the focal plane of the GRIN optical element, to thus map optical rays received at an input surface of the GRIN optical element to the focal plane of the GRIN optical element. 15. The detector system of claim 10 , further comprising: a memory; and algorithms for diagonalization of a linear system matrix using information supplied by the lenslets stored in the memory. 16. A detector system for imaging an optical signal received by a graded index (GRIN) optical element to account for known variations in a graded index distribution of the GRIN optical element, where the GRIN optical element has an input surface and an output surface, the detector system comprising: a plurality of optical detector elements in the form of lenslets to receive optical rays received by the GRIN optical element at a plurality of locations on the output surface, the output surface forming a focal plane of the GRIN optical element, each said lenslet including an associated plurality of pixels; the lenslets disposed adjacent the output surface of the GRIN optical element; ray processing software configured to map the received optical rays to a plurality of different, specific locations on the focal plane of the GRIN optical element based on the known variations in the graded index distribution of the GRIN optical element; a processor; a memory in communication with the processor for storing algorithms for diagonalization of a linear system matrix, used by the processor; the processor configured to use the algorithms to: calculate a distribution of both an intensity and an angle of the received optical rays at each one of the plurality of specific locations on the focal plane of the GRIN optical element; and to modify both the intensity and angle of the received optical rays, based on the calculated distribution of the intensity and angle of the received optical rays, to account for the known variations in the graded index distribution of the GRIN optical element. 17. The detector system of claim 16 , wherein each of the lenslets each include an associated plurality of pixels for receiving at least a subplurality of the optical signals. 18. The detector system of claim 17 , wherein the lenslets are sufficient in number and dimensions to cover an entire area of the output surface of the GRIN optical element.