Spatially interleaved polarization converter for LCOS display

What is claimed is: 1. A spatially-interleaved polarization converter comprising: optical elements including an input lenslet array, a first double-pass quarter-wave retarder, a second double-pass quarter-wave retarder, a polarizing beam splitter (PBS), and a wave-retarder array; the input lenslet array having a plurality of input lenslets with parallel respective lens optical axes, the wave-retarder array having a noncontiguous plurality of half-wave retarders with parallel respective retarder optical axes that are parallel to the lens optical axes; the PBS having a planar beam-splitting element located (a) between the input lenslet array and the wave-retarder array and (b) between the first double-pass quarter-wave retarder and the second double-pass quarter-wave retarder; the optical elements being configured to convert an input light beam to an output light beam having a plurality of first s-polarized beamlets interleaved with a plurality of second s-polarized beamlets. 2. The polarization converter of claim 1 , the planar beam-splitting element being the only beam-splitting element of the polarization converter that splits the input light beam. 3. The polarization converter of claim 1 , further comprising an output lenslet array between the PBS and the wave-retarder array, the PBS being between the input lenslet array and the output lenslet array. 4. The polarization converter of claim 3 , the input lenslet array and the output lenslet array opposing one another and being substantially parallel. 5. The polarization converter of claim 3 , the output lenslet array having a plurality of output lenslets each having an output lenslet surface; each input lenslet having an input lenslet surface; wherein the input lenslet surfaces and output lenslet surfaces each have a same radius of curvature and same conic constant. 6. The polarization converter of claim 3 , the PBS being a PBS cube, the input lenslet array being on a first side of the PBS cube, the output lenslet array being on a second side of the PBS cube opposite the first side, the first double-pass quarter-wave retarder being on a third side of the PBS cube, and the second double-pass quarter-wave retarder being on a fourth side of the PBS cube opposite the third side. 7. The polarization converter of claim 1 , an input lenslet lacking axial symmetry. 8. The polarization converter of claim 1 , the planar beam-splitting element being orientated at angle with respect to the lens optical axes and retarder optical axes, the angle being between 40°and 50°. 9. The polarization converter of claim 1 , the first and second double-pass quarter-wave retarders opposing one another and being substantially parallel, and being orthogonal to the input lenslet array. 10. The polarization converter of claim 1 , the first and second double-pass quarter-wave retarders opposing one another and being substantially parallel, the PBS being positioned therebetween. 11. The polarization converter of claim 1 , the optical elements being configured and arranged to collectively transmit each of the plurality of second s-polarized output beamlets at an angle with respect to a first s-polarized output beamlet not exceeding ten degrees. 12. The polarization converter of claim 1 , the optical elements being configured and arranged to collectively transmit each of the plurality of first s-polarized output beamlets at an angle with respect to the input light beam not exceeding ten degrees. 13. The polarization converter of claim 1 , at least one of the first and second double-pass quarter-wave retarders including at least one of a planar mirror and a concave mirror. 14. An image projector comprising: a spatially-interleaved polarization converter having optical elements including an input lenslet array and an output lenslet array, and being capable of transmitting incident light thereon as converted light having a single common polarization state; and a projector assembly having a pixel array and being capable of reflecting the converted light; the output lenslet array and the projector assembly being part of an imaging system that images the input lenslet array to a top surface of the pixel array. 15. The image projector of claim 14 : the optical elements further including a first double-pass quarter-wave retarder, a second double-pass quarter-wave retarder, a polarizing beam splitter (PBS), and a wave-retarder array; the input lenslet array having a plurality of input lenslets with parallel respective lens optical axes, the wave-retarder array having a noncontiguous plurality of half-wave retarders with parallel respective retarder optical axes that are parallel to the lens optical axes; the PBS having a planar beam-splitting element located (a) between the input lenslet array and the wave-retarder array and (b) between the first double-pass quarter-wave retarder and the second double-pass quarter-wave retarder; and the optical elements being configured to convert an input light beam to an output light beam having a plurality of first s-polarized beamlets interleaved with a plurality of second s-polarized beamlets. 16. The image projector of claim 14 , the imaging system further comprising a lens unit between the output lenslet array and the projector assembly. 17. The image projector of claim 14 , further comprising an illuminator capable of producing the incident light. 18. The image projector of claim 14 , one or both of the input lenslet array and a sub-array of lenslets therein having an aspect ratio equal to an aspect ratio of the pixel array. 19. A method for converting an input light beam having multiple linear polarization states to an output light beam having a single common polarization state comprising: transmitting the input light beam as a plurality of beamlets each having an s-polarized component and a p-polarized component; splitting each beamlet into a respective transmitted p-polarized beamlet and a respective reflected s-polarized beamlet; converting each transmitted p-polarized beamlet to a respective first s-polarized output beamlet; and spatially interleaving the reflected s-polarized beamlets with the first s-polarized output beamlets, resulting in the output beam. 20. The method of claim 19 , the step of spatially interleaving comprising: converting each reflected s-polarized beamlet to a respective intermediate p-polarized beamlet; converting each intermediate p-polarized beamlet to a respective second s-polarized output beamlet; and reflecting each second s-polarized output beamlet in a direction substantially parallel to at least one first s-polarized output beamlet.