Reconfigurable phase change material masks for electro-optical compressive sensing

The invention claimed is: 1. An optical system comprising: a layer of reconfigurable phase-change material (PCM) comprising a plurality of individually controllable pixel areas at a first resolution, each individually controllable pixel area being variable between a first refractive index and a second refractive index; said PCM layer being disposed at an image plane of the optical system and configured to pass incident radiation in accordance with a first mask pattern through the PCM layer in a downstream direction toward a photo-detector comprising a plurality of detector elements at a second resolution, where the second resolution is a lower resolution than the first resolution; and a PCM controller configured to control the plurality of individually controllable pixel areas to have respective refractive indices in accordance with the first mask pattern. 2. The optical system of claim 1 , the PCM controller including a voltage source; and the PCM controller being operably connected to the plurality of individually controllable pixel areas, the PCM controller configured to provide one of first voltage level to set a respective individually controllable pixel area to have the first refractive index and a second voltage level to set the respective individually controllable pixel area to have the second refractive index. 3. The optical system of claim 2 , where the first voltage level is six volts. 4. The optical system of claim 1 , further comprising: a voltage source operably connected to the PCM controller; where the PCM controller comprises a multiplexer PCM controller; and where the PCM controller is configured to control the voltage source such that the voltage source provides one of a first voltage level to set a respective individually controllable pixel area to have the first refractive index and a second voltage level to set the respective individually controllable pixel area to have the second refractive index. 5. The optical system of claim 1 , further comprising a laser source; the PCM controller being operably connected to the laser source; the laser source configured to provide one of a first laser irradiation to a respective individually controllable pixel area to set the respective individually controllable pixel area to the first refractive index and a second laser irradiation to the respective individually controllable pixel area to set the respective individually controllable pixel area to the second refractive index. 6. The optical system of claim 1 , the PCM controller including a laser source; the laser source configured to provide one of a first laser irradiation to a respective individually controllable pixel area to set the respective individually controllable pixel area to the first refractive index and a second laser irradiation to the respective individually controllable pixel area to set the respective individually controllable pixel area to the second refractive index. 7. The optical system of claim 6 , where the first laser irradiation is continuous wave (CW) irradiation and the second laser irradiation is pulsed irradiation. 8. The optical system of claim 1 where the plurality of individually controllable pixel areas is aggregated into a plurality of superpixels. 9. The optical system of claim 8 , where said plurality of superpixels is controlled by the PCM controller such that each superpixel of the plurality of superpixels may be set to have a particular imaging mask pattern by changing the respective refractive indices of the plurality of individually controllable pixel areas within each superpixel. 10. The mask optical system of claim 8 , where the photo-detector is an infra-red detector, where each superpixel corresponds to a pixel area of a plurality of pixel areas of the infra-red detector; where the individually controllable pixel areas having the first refractive index are opaque to infra-red radiation; and where the individually controllable pixel areas having the second refractive index are transparent to infra-red radiation. 11. The optical system of claim 8 , where each superpixel in the optical system is the same size and shape. 12. The optical system of claim 8 , where each superpixel corresponds to a pixel of the photo-detector. 13. The optical system of claim 1 , further comprising a second layer comprising doped silicon or alumina disposed beneath the PCM layer, where switching properties of the optical system are determined based on a thickness of the doped silicon or alumina layers. 14. The optical system of claim 1 , where each individually controllable pixel area may be set to a refractive index value within a range of values between the first refractive index and the second refractive index, inclusive. 15. The optical system of claim 1 , where: the PCM comprises Ge 2 Sb 2 Te 5 (GST); the first refractive index is associated with a crystallized state of GST; and the second refractive index is associated with an amorphous state of GST. 16. The optical system of claim 1 , where the first mask pattern corresponds to an imaging mask for compressive imaging. 17. The optical system of claim 1 , further including: an index variation layer of ZnS—SiO 2 disposed beneath the PCM layer; a layer of Aluminum disposed beneath the index variation layer; and a layer of glass disposed beneath the layer of Aluminum; where the photo-detector is disposed beneath the layer of glass such that incoming radiation to be detected by the photo-detector must pass through the PCM layer, the index variation layer, the layer of Aluminum, and the layer of glass before being detected by the photo-detector. 18. The optical system of claim 1 , further comprising: the photo-detector, where the photo-detector is configured to generate image data quantifying incident radiation on the plurality of detector elements; where the PCM controller is further configured to iteratively control the plurality of individually controllable pixel areas to have respective refractive indices in accordance with a plurality of different mask patterns; and where the photo-detector is configured to generate the image data for each of the plurality of different mask patterns.