Systems and methods for computed tomography

The invention claimed is: 1. A computed tomography (CT) system, comprising: an X-ray tube including a cathode and a target, and an X-ray controller including one or more processors having executable instructions stored in a non-transitory memory of the CT system that, when executed, cause the one or more processors to: during a first view of a CT scan of an object, focus an electron beam generated by the cathode at a first focal spot on a target of the X-ray tube, the first focal spot of a first size; during a second view of the CT scan, focus the electron beam at a second focal spot on the target, the second focal spot of a second size, the second size different from the first size; and reconstruct an image of the object from projection data including the first view and the second view; wherein; the CT scan is an mA modulated scan, and the first size is selected based on a first amount of current applied to the cathode in accordance with an mA modulation profile, the second size is selected based on a second amount of current applied to the cathode in accordance with the mA modulation profile, the second amount different from the first amount, and a total number of views of the CT scan is divided into a plurality of portions of consecutive views, each portion of the plurality of portions based on a corresponding range of current values of the mA modulation profile, and the electron beam is focused to generate a focal spot of a different size for a duration of each portion. 2. The CT system of claim 1 , wherein, prior to reconstructing the image, a plurality of projection views used to reconstruct the image are filtered to match a spatial resolution of a projection view at a larger spot size used throughout an acquisition performed using the CT system. 3. The CT system of claim 1 , wherein the first view and the second view are within a continuous X-ray exposure. 4. The CT system of claim 1 , wherein: the first size is selected to be a smallest size possible for the first amount of current that does not exceed a power limit for an amount of concentrated energy within the first focal spot on the target; and the second size is selected to be a smallest size possible for the second amount of current that does not exceed a power limit for an amount of concentrated energy within the second focal spot on the target. 5. The CT system of claim 1 , wherein the different sizes of focal spots are small, medium, large, and extra-large. 6. The CT system of claim 1 , wherein the current value ranges are overlapping. 7. The CT system of claim 6 , wherein an amount of current falls within two overlapping current ranges, and a focal spot size for the amount of current is selected based on an attenuation path length through a scanned object. 8. The CT system of claim 1 , wherein: focusing the electron beam at the first focal spot further comprises performing a first adjustment to at least one of electrostatic controls and/or electromagnetic controls of the X-Ray controller, where performing the first adjustment to the electrostatic controls includes adjusting a first voltage delivered at an electrode of the CT system, and performing the first adjustment to the electromagnetic controls includes adjusting one or more currents delivered to one or more magnets of the CT system; and focusing the electron beam at the second focal spot further comprises performing a second adjustment to at least one of the electrostatic controls and/or electromagnetic controls, the second adjustment different from the first adjustment. 9. The CT system of claim 8 , wherein the first adjustment is based on a first amount of current applied to the cathode in accordance with a mA modulation profile, and the second adjustment is based on a second amount of current applied to the cathode in accordance with the mA modulation profile. 10. The CT system of claim 1 , wherein prior to initiating the CT scan, the CT system is calibrated for a plurality of different focal spots, each different focal spot corresponding to an exclusive current range at which the focal spot is used. 11. The CT system of claim 10 , wherein calibrating the CT system for the plurality of different focal spots further comprises calibrating the CT system for a corresponding current range of each focal spot of the plurality of different focal spots, and not calibrating the CT system for the focal spot for current ranges outside the corresponding current range. 12. A method for a computed tomography (CT) system, the method comprising: reconstructing an image of a scanned object from projection view data acquired during an mA modulated scan performed by the CT system, wherein: the image is reconstructed from a first portion of the projection view data, the first portion acquired using a focal spot of a first size, the first size selected based on a first amount of current applied to the cathode in accordance with an mA modulation profile, and a second portion of the projection view data, the second portion acquired using a focal spot of a second size, the second size selected based on a second amount of current applied to the cathode in accordance with the mA modulation profile, the second amount different from the first amount; and a total number of views of the CT scan is divided into a plurality of portions of consecutive views, each portion of the plurality of portions based on a corresponding range of current values of the mA modulation profile, and the electron beam is focused to generate a focal spot of a different size for a duration of each portion. 13. The method of claim 12 , wherein the first portion of projection view data is corrected using a first calibration vector, the first calibration vector selected based on the focal spot of the first size; and the second portion of projection view data is corrected using a second calibration vector, the second calibration vector selected based on the focal spot of the second size. 14. The method of claim 12 , further comprising, during a backprojection process of image reconstruction, adjusting a resolution of a projection view through an object scanned by the CT system as a function of focal spot size for the projection view. 15. The method of claim 14 , wherein adjusting the resolution of the projection view as a function of focal spot size further comprises pre-filtering the projection view as a function of a larger focal spot size for the projection view to match a spatial resolution across a plurality of views. 16. A method, comprising: during a scan performed using a computed tomography (CT) system: dividing a total number of views of the CT scan into a plurality of portions of consecutive views, each portion of the plurality of portions based on a corresponding range of current values of an mA modulation profile of the scan, and focusing an electron beam to generate a focal spot of a different size for a duration of each portion; performing a first calibration of a first portion of the plurality of portions using a first set of calibration vectors selected for a first focal spot of a first size, the first set of calibration vectors covering a first range of kV/mA settings; and performing a second calibration of a second portion of the plurality of portions using a second set of calibration vectors selected for a second focal spot of a second size, the second set of calibration vectors covering the second range of kV/mA settings, the second range of kV/mA settings different from the first range of kV/mA settings. 17. The method of claim 16 , wherein the method is applied to the X-