Polarization filtering for window self-emission due to aero-thermal heating

I claim: 1. An optical system for use with a flight vehicle subject to aero-thermal heating, said optical system comprising: an optical window having interior and exterior surfaces with a curvature with respect to a central axis, said optical window configured such that incident radiation from a target passes through both said interior and exterior surfaces each of which induces a P-polarization to the incident target radiation within a plane of incidence, said optical window configured to self-emit radiation that passes only through said interior surface which induces a P-polarization to the self-emitted radiation within the plane of incidence, said self-emitted radiation overlapping the spectrum of the target radiation; focusing optics comprising an entrance pupil offset from the central axis to look through an off-axis segment of the optical window, said focusing optics configured to route incident radiation along an optical path and focus the incident radiation at a focal plane; a detector at or near the focal plane configured to sense incident radiation; a polarizer positioned in the optical path between the optical window and the detector, said polarizer comprising at least one filter pixel that imparts a linear polarization of a certain angular value to filter the incident radiation as a function of the polarization of the incident radiation; and a mechanism configured to align said at least one filter pixel to the P-polarization within the plane of incidence. 2. The optical system of claim 1 , further comprising: an airframe; and a propulsion system configured to propel the airframe towards a target at speeds greater than Mach 5. 3. The optical system of claim 1 , wherein said target radiation is at least 5% more P-polarized than said self-emitted radiation. 4. The optical system of claim 1 , wherein said polarizer comprises a sheet polarizer having only a single filter pixel, said mechanism fixing the alignment of said sheet polarizer to pass P-polarized radiation in the plane of incidence thereby modulating the intensity of incident radiation as a function of its P-polarization and increasing a contrast ratio of target radiation to self-emitted radiation. 5. The optical system of claim 1 , wherein said polarizer comprises a sheet polarizer having only a single filter pixel, said optical system further comprising: an outer gimbal configured to rotate about a first rotation axis; and an inner gimbal mounted on the outer gimbal, said inner gimbal configured to rotate the entrance pupil about a second rotation axis perpendicular or skew to the first rotation axis, said mechanism mounting the sheet polarizer on the inner gimbal in alignment to the P-polarization in the plane of incidence and remaining aligned as the outer and inner gimbals rotate about the first and second rotation axes, respectively. 6. An optical system for use with a flight vehicle subject to aero-thermal heating, said optical system comprising: an optical window having interior and exterior surfaces with a curvature with respect to a central axis, said optical window configured such that incident radiation from a target passes through both said interior and exterior surfaces each of which induces a P-polarization to the incident target radiation within a plane of incidence, said optical window configured to self-emit radiation that passes only through said interior surface which induces a P-polarization to the self-emitted radiation within the plane of incidence, said self-emitted radiation overlapping the spectrum of the target radiation; focusing optics comprising an entrance pupil offset from the central axis to look through an off-axis segment of the optical window, said focusing optics configured to route incident radiation along an optical path and focus the incident radiation at a focal plane; a detector at or near the focal plane configured to sense incident radiation, wherein the detector comprises a pixelated focal plane array (FPA); a polarizer positioned in the optical path between the optical window and the detector, wherein the polarizer comprises a microgrid polarizer array having a plurality of polarized pixelated filter sub-arrays positioned at the FPA or an intermediate image of the focal plane, each sub-array comprising three or more filter pixels Q of which at least two filter pixels impart a linear polarization of a certain and different angular value to filter the incident radiation as a function of the polarization of the incident radiation; a mechanism configured to align the microgrid polarizer array such that at least one of the filter pixels that imparts a linear polarization is aligned to the P-polarization in the plane of incidence; and a processor configured to read out and process multiple groupings of three or more FPA pixels L<=Q to compute an Angle of Linear Polarization (AoLP) image, wherein Q is defined as the number of filter pixels in each said sub-array and L is defined as the number of FPA pixels in each said grouping. 7. The optical system of claim 6 , wherein each sub-array comprises at least two filter pixels that are aligned to the P-polarization in the plane of incidence. 8. The optical system of claim 6 , wherein each sub-array is a 2×2 array of filter pixels that impart linear polarizations of 0, 45, 90 and 135 degrees, respectively, with one said linear polarization aligned to the P-polarization in the plane of incidence. 9. The optical system of claim 6 , wherein a data reduction matrix for the microgrid polarizer is calibrated to reduce P-polarization bias in the AoLP image. 10. The optical system of claim 6 , wherein the microgrid polarizer is positioned off-gimbal at the FPA, said mechanism fixing the alignment the microgrid polarizer array such that at least one of the filter pixels that imparts a linear polarization is aligned to the P-polarization in the plane of incidence. 11. The optical system of claim 6 , further comprising; an outer gimbal configured to rotate about a first rotation axis; and an inner gimbal mounted on the outer gimbal, said inner gimbal configured to rotate the entrance pupil about a second rotation axis perpendicular or skew to the first rotation axis, said mechanism mounting the microgrid polarizer on the inner gimbal at an intermediate image of the focal plane, said microgrid polarizer mounted such that said at least one filter pixel is aligned to the P-polarization in the plane of incidence and remains aligned as the outer and inner gimbals rotate about the first and second rotation axes, respectively. 12. The optical system of claim 6 , further comprising; an outer gimbal configured to rotate about a first rotation axis; and an inner gimbal mounted on the outer gimbal, said outer gimbal configured to rotate the entrance pupil about a second rotation axis perpendicular or skew to the first rotation axis, said mechanism mounting the microgrid polarizer off-gimbal at the FPA such that said at least one filter pixel is aligned to the P-polarization in the plane of incidence at known angular positions of the inner and outer gimbal, said mechanism configured to rotate the outer and inner gimbals to the known angular positions to readout the sensed incident radiation from the FPA. 13. The optical system of claim 1 , wherein said polarizer comprises a dynamic microgrid array having a plurality of switchable polarized filter pixels. 14. The optical system of claim 13 , wherein said dynamic microgrid array is configurable to switch all of the polarized filter pixels to the same certain angular value to pass P-polarized radiation and to switch the polarized filter pixels