Systems and methods for X-ray imaging

The invention claimed is: 1. A multi-energy X-ray imaging system, comprising: an X-ray source configured to emit X-rays toward an imaging volume; an X-ray detector configured to produce an electrical signal corresponding to the intensity of the X-rays that reach the X-ray detector after passing through the imaging volume; a filtering device comprising an array of micro-filters each configured to transition between an X-ray filtering position and an X-ray non-filtering position, and being positioned between the X-ray source and the X-ray detector; and a controller programmed to acquire a first set of projection data when applying a first energy spectrum by controlling the X-ray source to emit the X-rays with the first energy spectrum and controlling one or more of the micro-filters to be in the non-filtering position, and to further acquire a second set of projection data when applying a second energy spectrum with a mean energy greater than the mean energy of the first energy spectrum by controlling the X-ray source to emit the X-rays at the second energy spectrum and controlling one or more of the micro-filters to be in the filtering position. 2. The multi-energy X-ray imaging system of claim 1 , wherein the controller is programmed to transition one or more of the micro-filters between the X-ray filtering position and the X-ray non-filtering position in less than approximately 10 microseconds. 3. The multi-energy X-ray imaging system of claim 1 , wherein when one or more of the micro-filters are in the non-filtering position, greater than 75% of the emitted X-rays pass through the filtering device. 4. The multi-energy X-ray imaging system of claim 1 , comprising a processor configured to process the first set of projection data and the second set of projection data to construct one or more multi-energy X-ray images. 5. The multi-energy X-ray imaging system of claim 1 , wherein the controller is programmed to transition the one or more micro-filters between the filtering position and the non-filtering position via one of electrostatic, thermal, or magnetic actuation. 6. An X-ray imaging system, comprising: an X-ray source configured to emit X-rays toward an imaging volume; an X-ray detector configured to produce an electrical signal corresponding to the intensity of the X-rays that reach the X-ray detector after traveling through the imaging volume; a filtering device positioned between the X-ray source and the X-ray detector, the filtering device comprising one or more micro-filters each configured to transition between an X-ray filtering position and an X-ray non-filtering position; and a controller programmed to acquire a set of projection data when controlling the one or more micro-filters to be in either a non-filtering position or a non-filtering position so as to modulate one or more of the X-ray flux or spectral characteristics within the imaging volume or at the detector. 7. The X-ray imaging system of claim 6 , wherein the one or more of the micro-filters, when in the filtering position, block portions of the X-rays beam outside one or more regions of interest in the object. 8. The X-ray imaging system of claim 6 , wherein the controller is further programmed to individually control one or more of the micro-filters to one or more of modify the spectral characteristics of the X-ray beam incident on the imaging volume and vary the attenuation within a field of view to provide a uniform flux profile at the X-ray detector during acquisition of the projection data. 9. The X-ray imaging system of claim 6 , wherein the controller is further programmed to individually control one or more of the micro-filters to block a portion of the effective area of a plurality of detector cells of the X-ray detector during acquisition of the projection data. 10. A multi-energy X-ray imaging method, comprising: controlling an X-ray source to emit X-rays with a first energy spectrum; controlling one or more of micro-filters, positioned between the X-ray source and an X-ray detector, to be in an X-ray non-filtering position when the X-ray source emits the X-rays with the first energy spectrum; controlling the X-ray source to emit the X-rays with a second energy spectrum with a mean energy greater than the mean energy of the first energy spectrum; and controlling the one or more micro-filters to be in an X-ray filtering position when the X-ray source emits the X-rays with the second energy spectrum. 11. The multi-energy X-ray imaging method of claim 10 , comprising acquiring a first set of projection data when applying the first energy spectrum by detecting X-rays that pass between the array of micro-filters and through an imaging volume, and acquiring a second set of projection data when applying the second energy spectrum by detecting X-rays that traverse the array of micro-filters and through the imaging volume. 12. The multi-energy X-ray imaging method of claim 11 , comprising constructing one or more multi-energy X-ray images from the first set of projection data and the second set of projection data. 13. The multi-energy X-ray imaging method of claim 10 , wherein controlling the array of micro-filters to be in the X-ray filtering position or to be in the X-ray non-filtering position comprises altering the physical position of micro-filters in the array. 14. The multi-energy X-ray imaging method of claim 13 , wherein altering the physical position of micro-filters in the array comprises pivoting each of the miocro-filters in the array of micro-filters on a respective torsion spring. 15. The multi-energy X-ray imaging method of claim 13 , wherein altering the physical position of the micro-filters in the array comprises applying one of a voltage, a magnetic field, or a thermal field to the micro-filters in the array to alter the configuration of the micro-filters in the array to the X-ray filtering position or the X-ray non-filtering position. 16. An X-ray imaging method, comprising: controlling an X-ray source to emit X-rays; controlling one or more of micro-filters, positioned between the X-ray source and an X-ray detector, each configured to transition between an X-ray filtering position and an X-ray non-filtering position, so as to modulate one or more of the X-ray flux or spectral characteristics within the imaging volume or at the detector; and controlling acquisition of projection data by the X-ray detector when the one or more micro-filters are configured in either the X-ray filtering position or the X-ray non-filtering position. 17. The X-ray imaging method of claim 16 , wherein the one or more of the micro-filters when in the filtering position, block portions of the X-rays beam outside one or more regions of interest in the object. 18. The X-ray imaging method of claim 16 , wherein one or more of the micro-filters are individually controlled to vary the attenuation within a field of view, thereby achieving one or more of modifying the spectral characteristics of the X-ray beam incident on the imaging volume and providing a uniform flux profile at the X-ray detector during acquisition of the projection data. 19. The X-ray imaging method of claim 16 , wherein the one or more of the micro-filters are individually controlled to block a portion of the effective area of a plurality of detector cells comprising the X-ray detector during acquisition of the projection data. 20. The X-ray imaging method of claim 16 , wherein controlling the one or more micro-filters to transition between the X-ray filtering position and th