Low aberration, high intensity electron beam for X-ray tubes

What is claimed is: 1. An x-ray imaging system comprising: a) a detector positioned to receive x-rays; b) an x-ray tube configured to generate x-rays toward the detector from a focal spot surface, the x-ray tube comprising: 1. a target having the focal spot surface; and 2. a cathode comprising: i. a cathode cup; and ii. a flat emitter attached to cathode cup that can emit electrons toward the focal spot surface upon application of a voltage between the emitter and the target, the emitter having a non-rectangular emission area with angled edges thereon; and iii. a number of focus pads positioned around the non-rectangular emission area, wherein the non-rectangular emission area of the flat emitter comprises a cut-out pattern such that a back-and-forth current path is formed in the flat emitter and wherein the cut-out pattern includes a non rectangular emission area and a rectangular emission area. 2. The imaging system of claim 1 wherein the cut-out pattern is octagonal in shape. 3. The imaging system of claim 1 wherein the emission area is joined to a pair of non-emitting engagement tabs. 4. The imaging system of claim 1 wherein the focus pads can be biased to predetermined negative voltages relative to the emitter to reduce the size of the focal spot. 5. The imaging system of claim 1 wherein the cathode cup includes width and length electrodes to focus the electron beam. 6. The imaging system of claim 5 wherein the width and length electrodes can be biased to predetermined positive or negative voltages relative to the emitter to control the size of the focal spot. 7. The imaging system of claim 6 wherein the width and/or length electrodes can be biased to predetermined negative voltages relative to the emitter to cut off the electron beam. 8. The imaging system of claim 1 wherein the non-rectangular emission area includes a number of legs having opposed angled edges. 9. A method of manufacturing a cathode assembly for an x-ray tube comprising the steps of: a) providing an emitter having a non-rectangular emission area from which electrons emit when an electrical current is passed therethrough, wherein the non-rectangular emission area of the flat emitter comprises a ribbon-shaped cut-out pattern having back-and-forth legs that extend along the width of the emitter and form the non-rectangular emission area and a rectangular emission area; b) providing a cathode cup; c) attaching the cathode cup to a cathode support structure of the x-ray tube such that the cathode cup is electrically insulated from the cathode support structure; d) coupling a current supply lead and a current return lead to the cathode cup; and e) attaching the flat emitter to the cathode cup such that, when a current is provided by the current supply, electrons emit from the non-rectangular emission area and the rectangular emission area of the flat emitter toward a target of the x-ray tube. 10. The method of claim 9 wherein the step of attaching the flat emitter to the cathode cup comprises placing the non-rectangular emission area of the flat emitter adjacent a number of focus pads formed on the cathode cup. 11. The method of claim 9 wherein the legs include opposed angled edges. 12. The method of claim 9 wherein the cathode cup includes a number of width/length electrodes disposed adjacent the non-rectangular emission area, and further comprising the step of adjusting the width/length electrodes to alter a size of a focal spot of the electrons. 13. The method of claim 12 wherein the step of adjusting the width/length electrodes comprises adjusting either the height of the electrodes on the cathode cup or the bias voltage applied to the electrodes. 14. A cathode assembly for an x-ray tube comprising: a) a support structure; b) a cathode cup attached to the support structure; and c) a flat emitter attached to the cathode cup the flat emitter including at least one non-rectangular emission area thereon, and d) a number of focus pads positioned around the non-rectangular emission area, wherein the at least one non-rectangular emission area is formed of non-rectangular legs located within but not extending completely across a rectangular emission area. 15. The cathode assembly of claim 14 wherein the at least one non-rectangular emission area comprises a cut-out pattern such that a back-and-forth current path is formed in the flat emitter. 16. The cathode assembly of claim 15 wherein the cut-out pattern includes back-and-forth legs that extend along the width of the emitter. 17. The cathode assembly of claim 16 wherein the cut-out pattern includes back-and-forth legs with opposed angled edges that are spaced from the width of the emitter. 18. The cathode assembly of claim 17 wherein the cut-out pattern is octagonal shape. 19. The cathode assembly of claim 14 wherein the non-rectangular legs are parallel to one another.