Focusing structures with non-rectilinear focusing apertures

What is claimed is: 1. A cathode assembly comprising: a cathode head that defines a filament slot and an insert recess; a filament positioned in the filament slot that is capable of emitting electrons by thermionic emission; a cathode head insert that is configured to be received in the insert recess and positioned at least partially between the filament and an anode, the cathode head insert including a first sloped surface connected to a second sloped surface; and a non-rectilinear focusing aperture defined in the first sloped surface of the cathode head insert, the non-rectilinear focusing aperture being configured to shape an emission profile of electrons emitted by the filament. 2. The cathode assembly of claim 1 , wherein the non-rectilinear focusing aperture includes at least one curved edge that is oriented along a longitudinal dimension of the filament. 3. The cathode assembly of claim 1 , wherein the non-rectilinear focusing aperture includes: two linear edges oriented substantially perpendicular to a longitudinal dimension of the filament; and two curved edges oriented along the longitudinal dimension of the filament. 4. The cathode assembly of claim 3 , wherein the two curved edges are defined according to radii of curvature that include substantially equivalent magnitudes and substantially equivalent directions. 5. The cathode assembly of claim 3 , wherein the two curved edges are defined according to radii of curvature having a magnitude equal to about five times a length of the non-rectilinear focusing aperture. 6. The cathode assembly of claim 1 , wherein the cathode head defines a second filament slot and the cathode assembly further comprises: a second filament positioned within the second filament slot; and a second non-rectilinear focusing aperture defined in the second sloped surface of the cathode head insert, the second non-rectilinear focusing aperture being configured to shape an emission profile of electrons emitted by the second filament. 7. The cathode assembly of claim 6 , wherein: the non-rectilinear focusing aperture includes two linear edges oriented substantially perpendicular to a longitudinal dimension of the filament and two curved edges oriented along the longitudinal dimension of the filament; the two curved edges of the non-rectilinear focusing aperture are defined according to a first set of radii of curvature that include substantially equivalent magnitudes and substantially equivalent directions; the second non-rectilinear focusing aperture includes two linear edges oriented substantially perpendicular to a longitudinal dimension of the second filament and two curved edges oriented along the longitudinal dimension of the second filament; the two curved edges of the second non-rectilinear focusing aperture are defined according to a second set of radii of curvature that include substantially equivalent magnitudes and substantially equivalent directions; and the direction of the first set of radii of curvature is different from the direction of the second set of radii of curvature. 8. The cathode assembly of claim 6 , wherein: the first sloped surface is connected to the second sloped surface at a central joint; and the second non-rectilinear focusing aperture is symmetric to the non-rectilinear focusing aperture about the central joint. 9. A focusing structure configured to compensate for a lack of rectilinear conformity of a focal spot produced on an anode by emission of electrons by a filament, the focusing structure comprising: a first sloped surface; a second sloped surface connected to the first sloped surface; and a non-rectilinear focusing aperture defined in the first sloped surface, the non-rectilinear focusing aperture including two linear edges configured to be oriented substantially perpendicular to a longitudinal dimension of the filament and two curved edges configured to be oriented along the longitudinal dimension of the filament. 10. The focusing structure of claim 9 , wherein the non-rectilinear focusing aperture includes a curved profile in which the curved edges are substantially parallel to one another between the linear edges. 11. The focusing structure of claim 9 , wherein: the non-rectilinear focusing aperture includes an hourglass profile in which a central width is less than a distal width; and the curved edges are defined according to radii of curvature having substantially equivalent magnitudes and opposite directions. 12. The focusing structure of claim 9 , wherein the curved edges are defined according to radii of curvature having a magnitude equal to about five times a length of the non-rectilinear focusing aperture. 13. The focusing structure of claim 9 , wherein: the second sloped surface is connected to the first sloped surface at a central joint, a second non-rectilinear focusing aperture is defined in the second sloped surface, the second non-rectilinear focusing aperture is configured to shape an emission profile of electrons emitted by a second filament, and the second non-rectilinear focusing aperture includes two linear edges configured to be oriented substantially perpendicular to a longitudinal dimension of the second filament and two curved edges configured to be oriented along the longitudinal dimension of the second filament. 14. The focusing structure of claim 13 , wherein: the non-rectilinear focusing aperture includes a first curved profile; the second non-rectilinear focusing aperture includes a second curved profile; and the first curved profile is substantially symmetric to the second curved profile about the central joint. 15. An x-ray tube comprising: a cathode head having a filament slot defined therein in a first direction and that defines an insert recess; a filament capable of emitting electrons that is positioned within the filament slot such that a longitudinal dimension of the filament is oriented parallel to the first direction; an anode including a target surface on which a focal spot is produced due to impingement of electrons emitted from a filament; a cathode head insert that is configured to be received in the insert recess such that the cathode head insert is positioned at least partially between the filament and the anode, the cathode head insert including two sloped surfaces connected by a central joint; and a non-rectilinear focusing aperture defined in a first of the sloped surfaces, the non-rectilinear focusing aperture including at least one curved edge. 16. The x-ray tube of claim 15 , wherein the non-rectilinear focusing aperture includes two linear edges configured to be oriented substantially perpendicular to the longitudinal dimension of the filament and two curved edges configured to be oriented along the longitudinal dimension of the filament. 17. The x-ray tube of claim 15 , further comprising a second filament and a second non-rectilinear focusing aperture defined in a second of the sloped surfaces. 18. The x-ray tube of claim 17 , wherein: the second non-rectilinear focusing aperture is symmetric to the non-rectilinear focusing aperture about the central joint; and the second non-rectilinear focusing aperture is configured to shape an emission profile of electrons emitted by the second filament. 19. The x-ray tube of claim 15 , wherein the anode is a rotating anode.