Patent Number: 
Section: claims

1. A structure comprising:a first scintillating screen that converts an absorbed portion of incident radiation directed at the structure into light photons;a photosensor array;a second scintillating screen,a fiber optic plate between the photosensor array and the second scintillating screen, the photosensor array being between the first scintillating screen and the fiber optic plate, the second scintillating screen converts an absorbed portion of the incident radiation transmitted through the first scintillating screen, the photosensor array and the fiber optic plate, into light photons, where a surface of the first scintillating screen faces the photosensor array and a surface of the second scintillating screen faces the fiber optic plate,wherein the photosensor array is operable to capture at least a portion of the light photons from the first scintillating screen and the second scintillating screen and convert the captured light photons into electrical signals,wherein the fiber optic plate is a substrate for the photosensor array. 2. The structure of claim 1, wherein the photosensor array comprises a plurality of bidirectionally photosensitive storage elements for capturing the at least a portion of the light photons from the first scintillating screen and the second scintillating screen, switching elements where one switching element of the plurality of switching elements corresponds to one of the plurality of photosensitive storage elements, respectively, a transparent metal bias layer and a transparent 2D patterned metal layer, where the transparent 2D patterned metal layer faces the fiber optic plate. 3. The structure of claim 1, wherein the first scintillating screen comprises a scintillating structure having a first thickness, and the second scintillating screen comprises a scintillating structure having a second thickness, where the second thickness is greater than the first thickness. 4. The structure of claim 1, wherein the second scintillating screen further comprises a backing, the backing contacting a surface of the second scintillating screen opposite of a surface facing the fiber optic plate. 5. The structure of claim 1, wherein the first scintillating screen further comprises a backing, the backing of the first scintillating screen facing an incoming x-ray beam energy. 6. The structure of claim 1, wherein the first scintillating screen and the second scintillating screen are formed of a different type, the type being granular or columnar. 7. The structure of claim 1, wherein the fiber optic plate has a thickness between 1 mm and 3 mm, inclusive. 8. The structure of claim 2, wherein at least one of the transparent 2D patterned metal layer and the transparent metal bias layer comprises an optical filter to balance gain from the first scintillating screen and the second scintillating screen. 9. The structure of claim 8, wherein the optical filter comprising a layer of absorbing material. 10. The structure of claim 3, wherein a ratio of the first thickness to a combination of the first thickness and the second thickness is based on at least one of an incoming x-ray beam energy, a target spatial resolution performance or a target detective quantum efficiency. 11. An imaging system comprising:a processor configured to be in communication with a structure comprising:a first scintillating screen that converts an absorbed portion of incident radiation directed at the structure into light photons;a photosensor array; anda second scintillating screen;a fiber optic plate between the photosensor array and the second scintillating screen, the photosensor array being between the first scintillating screen and the fiber optic plate, the second scintillating screen converts an absorbed portion of the incident radiation transmitted through the first scintillating screen, the photosensor array and the fiber optic plate into light photons, where a surface of the first scintillating screen faces the photosensor array and a surface of the second scintillating screen faces the fiber optic plate,wherein the photosensor array is operable to capture at least a portion of the light photons from the first scintillating screen and the second scintillating screen and convert the captured light photons into electrical signals,wherein the fiber optic plate is the substrate for the photosensor arraythe processor is configured to:receive the electrical signals from the structure; andproduce the image having a plurality of pixels using the electrical signals. 12. The imaging system of claim 11, wherein the photosensor array comprises a plurality of bidirectionally photosensitive storage elements for capturing the at least a portion of the light photons from the first scintillating screen and the second scintillating screen, switching elements where one switching element of the plurality of switching elements corresponds to one of the plurality of photosensitive storage elements, respectively and a first metal layer and a second metal layer,wherein the first metal layer is a transparent metal bias layer and the second metal layer is a transparent 2D patterned metal layer, where the transparent 2D patterned metal layer faces the fiber optic plate, wherein the processor controls each row of switching elements using a scanning control unit, thereby connecting the corresponding photosensitive storage elements to amplifiers, whose outputs are digitized to pixel values for each row of the image. 13. A radiation detector comprising:a first radiation converter;a second radiation converter;a photosensor array;a fiber optic plate between the second radiation converter and the photosensor array, the photosensor array between the first radiation converter and the fiber optic plate, the fiber optic plate being a substrate for the photosensor array where a surface of the first radiation converter faces the photosensor array and a surface of the second radiation converter faces the fiber optic plate,the first radiation converter being configured to:receive and partially absorb incident penetrating radiation directed towards the radiation detector; andconvert the absorbed incident radiation into a burst of a plurality of light photons, a number of which reach the photosensor array and are detected;the second radiation converter being configured to:receive and partially absorb the portion of the incident radiation transmitted through the first radiation converter, the photosensor array and the fiber optic plate; andconvert the absorbed radiation into a burst of a plurality of light photons, a number of which reach the photosensor array and are detected,the photosensor array being configured to:respond a spatial pattern of the light photons from the first radiation converter and the second radiation converter by converting the light photons into an electrical signal pattern representative of a sum of the spatial pattern of the light photons from the first radiation converter and the spatial pattern of the light photons from the second radiation converter. 14. The radiation detector of claim 13, wherein the photosensor array comprises a first metal layer and a second metal layer, the first metal layer being directly in contact with the first radiation converter or being directly attached to the first radiation converter using an optical adhesive and the second metal layer being directly in contact with the fiber optic plate or being directly attached to the fiber optic plate using an optical adhesive.