Microgrid arrangement for integrated imaging polarimeters

We claim: 1. A microgrid imaging polarimeter, comprising a plurality of 2×4 identical arrays of eight wiregrid polarizers proximate to a focal plane, where each of the eight wiregrid polarizers comprises one of four different polarization orientations, where each of the four different polarization orientations is used by exactly two different wiregrid polarizers in each of the arrays, and each of the arrays represents a smallest periodic repeating, pattern of wiregrid polarizers in the microgrid imaging polarimeter, thereby widening an unaliased bandwidth available for image reconstruction by increasing a separation between spatially modulated Stokes components of the microgrid spectra, without affecting performance in a presence of noise. 2. The microgrid imaging polarimeter according to claim 1 , wherein each wiregrid polarizer corresponds to a corresponding detector pixel in the focal plane. 3. The microgrid imaging polarimeter of claim 1 , wherein the polarization orientations of the wiregrid polarizers in each 2×4 array, beginning from an arbitrary top left wiregrid polarizer of each array and continuing clockwise, are: 45 degrees; zero degrees; 315 degrees; 90 degrees; zero degrees; 45 degrees; 90 degrees; and, 315 degrees. 4. A microgrid imaging polarimeter, comprising: (a) a plurality of identical 2×4 arrays of eight wiregrid polarizers, where each of the eight wiregrid polarizers comprises one of four different polarization orientations, where each of the eight wiregrid polarizers comprises one of four different polarization orientations, where each of the four different polarization orientations is used by exactly two different wiregrid polarizers in each of the arrays, and each of the arrays represents a smallest periodic repeating pattern of wiregrid polarizers in the microgrid imaging polarimeter, thereby widening an unaliased bandwidth available for image reconstruction by increasing a separation between spatially modulated Stokes components of the microgrid spectra, without affecting performance in a presence of noise; (b) a plurality of detector pixels; and, (c) wherein each wiregrid polarizer is proximate to a corresponding detector pixel. 5. The microgrid imaging polarimeter according to claim 4 , wherein the polarization orientations of the wiregrid polarizers in each 2×4 array, beginning from an arbitrary top left wiregrid polarizer of each array and continuing clockwise, are: 45 degrees; zero degrees; 315 degrees; 90 degrees; zero degrees; 45 degrees; 90 degrees; and, 315 degrees. 6. A method for making a polarized image, comprising the steps of: (a) providing an imaging polarimeter, including: a plurality of identical 2×4 arrays of eight wiregrid polarizers proximate to a focal plane, where each of the eight wiregrid polarizers comprises one of four different polarization orientations, where each of the four different polarization orientations is used by exactly two different wiregrid polarizers in each of the arrays, and each of the arrays represents a smallest periodic repeating pattern of wiregrid polarizers in the microgrid imaging polarimeter, thereby widening are unaliased bandwidth available for image reconstruction by increasing a separation between spatially modulated Stokes components of the microgrid spectra, without affecting performance in a presence of noise; (ii) a plurality of detector pixels; and, (iii) wherein each wiregrid polarizer is proximate to a corresponding detector pixel. 7. The method for making a polarized image according to claim 6 , wherein the polarization orientations of the wiregrid polarizers in each 2×4 array, beginning from an arbitrary top left wiregrid polarizer of each array and continuing clockwise, are: 45 degrees; zero degrees; 315 degrees; 90 degrees; zero degrees; 45 degrees; 90 degrees; and, 315 degrees.