Patent Number: 
Section: claims

1. A mask apparatus for use in compressed sensing of incoming radiation, the mask apparatus comprising:a coded mask having a body portion comprised of a material that modulates the intensity of the incoming radiation;wherein the coded mask has a plurality of mask aperture regions that allow a higher transmission of the radiation relative to said body portion, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;wherein the coded mask is configured to rotate relative to the mask apparatus. 2. The mask apparatus of claim 1, wherein the coded mask is rectangular, circular, arcuate, cylindrical, hemispherical, segments of spheres, or spherical. 3. The mask apparatus of claim 1, wherein the coded mask is formed:i) from a material that modulates incoming gamma-ray radiation;ii) from a material that modulates incoming optical or infrared radiation;iii) from a material that modulates incoming neutron radiation; oriv) from a material that modulates both incoming gamma-ray radiation and neutrons. 4. The mask apparatus of claim 1, wherein:some of the mask aperture regions are modulating regions for gamma-rays and some of the mask aperture regions are modulating regions for neutrons. 5. The mask apparatus of claim 1, wherein:a) the mask apparatus has a horizontal field of view of 360°; orb) the coded mask is hemispherical and the mask apparatus has a field of view of 2π; orc) the coded mask is spherical and the mask apparatus has a field of view of nearly 4π. 6. The mask apparatus of claim 1, further comprising a radiation shield formed of a material that modulates the intensity of the incoming radiation; wherein the radiation shield has an opening that limits a field of view of detection of the incoming radiation. 7. The mask apparatus as claimed in claim 6, wherein the radiation shield:a) is cylindrical; and/orb) has an arcuate opening that limits the field of view to an arc defined by the opening. 8. The mask apparatus as claimed in claim 1, wherein the coded mask is:a) cylindrical and comprises one or more spiral structures that comprise one or more mask aperture regions; orb) cylindrical and comprises two spiral structures that comprise one or more mask aperture regions. 9. The mask apparatus as claimed in claim 1, wherein:the coded mask comprises two spiral structures that comprise one or more mask aperture regions;the mask apparatus comprises a further coded mask having a cylindrical body portion comprised of a material that modulates the intensity of the incoming radiation, and one or more slits that allow a higher transmission of the radiation relative to the body portion of the further coded mask, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;the coded mask and the further coded mask are configured to rotate relative to one another; androtation of the coded mask and the further coded mask relative to one another produces at least one coded aperture. 10. The mask apparatus as claimed in claim 1, wherein said modulation comprises attenuating or scattering said incoming radiation. 11. A mask apparatus for use in compressed sensing of incoming radiation, the mask apparatus comprising:a coded mask having a body portion comprised of a material that modulates the intensity of the incoming radiation;wherein the coded mask has a plurality of mask aperture regions that allow a higher transmission of the radiation relative to said body portion, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;wherein the coded mask is rectangular, arcuate, cylindrical, hemispherical, segments of spheres, or spherical; andwherein the coded mask is configured to rotate relative to the mask apparatus. 12. A radiation detection method, comprising:making compressed sensing measurements of radiation from one or more radiation sources with at least one radiation sensor and a mask apparatus, the mask apparatus comprising:a coded mask having a body portion comprised of a material that modulates the intensity of incoming radiation, the coded mask having a plurality of mask aperture regions that allow a higher transmission of the radiation relative to said body portion, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;wherein the coded mask is configured to rotate; andthe incoming radiation from the one or more radiation sources passes through the coded mask before detection by the at least one radiation sensor. 13. The radiation detection method as claimed in claim 12, wherein the coded mask is rectangular, circular, arcuate, cylindrical, hemispherical, segments of spheres, or spherical. 14. The radiation detection method as claimed in claim 12, wherein:the mask apparatus comprises a further coded mask having a body portion comprised of a material that modulates the intensity of incoming radiation and a plurality of mask aperture regions that allow a higher transmission of the radiation relative to the body portion of the further coded mask, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;the coded mask and the further coded mask are configured to rotate relative to one another; andthe method further comprises:a) indexing the coded mask in rotation angle for a full revolution, thenb) indexing the further coded mask by a single column. 15. The method of decommissioning, decontamination, environmental monitoring, medical imaging, astronomy or security, comprising a radiation detection method as claimed in claim 12. 16. A compressed sensing radiation imager, comprising:at least one radiation sensor located within a mask apparatus that comprises:a coded mask having a body portion comprised of a material that modulates the intensity of incoming radiation, the coded mask having a plurality of mask aperture regions that allow a higher transmission of the radiation relative to said body portion, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;wherein the coded mask is configured to rotate;wherein the imager is configured to make compressed sensing measurements of radiation from one or more radiation sources and to generate radiation image data from the compressed sensing measurements. 17. The radiation imager as claimed in claim 16, wherein the at least one radiation sensor comprises:i) at least one gamma-ray radiation sensor, such that the radiation imager constitutes a gamma-ray radiation imager;ii) at least one neutron sensor, such that the radiation imager constitutes a neutron radiation imager;iii) at least one gamma-ray radiation sensor and at least one neutron radiation sensor, such that the radiation imager constitutes a gamma-ray radiation and neutron radiation imager;iv) at least one dual modality sensor; orv) at least one dual modality sensor that senses both gamma-rays and neutrons. 18. The radiation imager as claimed in claim 16, further configured to capture an optical, infrared or other wavelength image and to output image data. 19. The radiation imager as claimed in claim 16, wherein the imager is configured to overlay the radiation image data and an optical or infrared image corresponding to a common field of view. 20. The radiation imager as claimed in claim 16, wherein the coded mask is:a) rectangular,b) circular,c) arcuate,d) hemispherical,e) segments of spheres,f) spherical,g) cylindrical,h) cylindrical and comprises one or more spiral structures that comprise one or more mask aperture regions, orh) cylindrical and comprises two spiral structures that comprise one or more mask aperture regions. 21. The radiation imager as claimed in claim 16, wherein:the coded mask is cylindrical and includes one or more spiral structures that comprise one or more mask aperture regions;the mask apparatus comprises a further coded mask having a cylindrical body portion comprised of a material that modulates the intensity of the incoming radiation, and one or more slits that allow a higher transmission of the radiation relative to the body portion of the further coded mask, the higher transmission being sufficient to allow reconstruction of compressed sensing measurements;the coded mask and the further coded mask are configured to rotate relative to one another; androtation of the coded mask and the further coded mask relative to one another produces at least one coded aperture.