Patent Number: 
Section: claims

1. A computed tomography apparatus comprising:a gantry which rotates on an axis of rotation around an examination region;a dual beam radiation source mounted on the gantry which dual beam radiation source propagates at least two cone-beams of radiation into the examination region, the dual beams of the dual beam radiation source being aligned in a direction parallel with the axis of rotation and oriented toward each other providing overlap of cone beams within the field of view;a common detector which detects the radiation from the two cone-beams which has passed through the examination region;a pulse controller which pulses the cone-beams of radiation alternatively; andan attenuation system interposed between the radiation sources and the examination region for cone-angle dependent filtering of the cone beams in an axial direction, the attenuation system including filters of thickness which increase in the direction of overlap of the dual beams in the field of view. 2. A computed tomography apparatus comprising:a gantry which rotates on an axis of rotation around an examination region;a common detector which has a field of view over which the detector detects radiation which has passed through the examination region;a dual beam radiation source mounted on the gantry which dual beam radiation source propagates at least two overlapping cone-beams of radiation into the examination region, each cone beam having an apex at a focal point of the cone beam, one face of the cone beam lying in a plane orthogonal to the axes of rotation to define one face of the field of view and another face extending across the field of view at an obtuse angle relative to the axis of rotation, wherein an attenuation system filters a first ray passing through a field of view of the detector within the examination region at an oblique angle more than a second ray passing through the field of view at a less oblique angle. 3. A computed tomography apparatus comprising:a gantry which rotates on an axis of rotation around an examination region;a dual beam radiation source mounted on the gantry which dual beam radiation source propagates at least two cone-beams of radiation into the examination region;a common detector which detects the radiation from the two cone-beams which has passed through the examination region;a pulse controller which pulses the cone-beams of radiation alternatively; andan attenuation system interposed between the radiation sources and the examination region for cone-angle dependent filtering of the cone beams, the attenuation system attenuating rays less as the ray direction is more orthogonal of the axis of rotation and attenuates more as the ray direction is less orthogonal of the axis of rotation. 4. The computed tomography apparatus of claim 3, wherein the dual beams of the dual beam radiation source are aligned in a direction parallel with the axis of rotation, and oriented toward each other providing overlap of cone beams within the field of view. 5. The computed tomography apparatus of claim 3, wherein the attenuation system includes filters of a thickness which varies in a scanning direction. 6. The computed tomography apparatus of claim 3, wherein the cone beams have a most oblique cone angle toward a center of the field of view and the attenuation system includes filters of thickness which have a maximum thickness at a most oblique cone angle of each cone beam. 7. The computed tomography apparatus of claim 3, wherein the maximum attenuation is at least 20%. 8. The computed tomography apparatus of claim 3, wherein the maximum attenuation is at least about 50%. 9. A computed tomography apparatus comprising:spaced radiation sources with first and second anodes aligned in a direction of scanning, each anode propagating a cone beam of radiation into an examination region, the cone beams being oriented toward each other such that the cone-beams overlap within the examination region;a common detector which detects the radiation which has passed through the examination region from both of the two anodes; andan attenuation system interposed between the anodes and the examination region, the attenuation system including a filter which attenuates the cone beams more towards a center of the examination region and less towards edges of the examination region. 10. The computed tomography apparatus of claim 9, wherein the first and second anodes are anodes of a common stereo x-ray tube. 11. The computed tomography apparatus of claim 9, further comprising a pulse controller for alternately pulsing the first and second anodes. 12. The computed tomography apparatus of claim 9, further comprising:a reconstruction processor which receives image data from the detector, the reconstruction processor digitally applying a cone angle-dependent weighting to the image data. 13. A method of computed tomography imaging comprising:projecting first and second cone beams of radiation from a single source towards an examination region;prior to the examination region:attenuating the first and second cone beams to form attenuated first and second cone-beams such that attenuation of each beam is greater toward a center of the examination region and less toward edges of the examination region; andacquiring radiation data from the examination region. 14. The method of claim 13, further comprising:reconstructing an image based on the acquired radiation data. 15. The method of claim 14, further comprising:down-weighting rays more oblique in an axial direction more strongly than rays less oblique in the axial direction in reconstructing the image. 16. The method of claim 13, further comprising:aligning the cone beams along the direction of scanning , and orienting the cone beams toward each other providing overlap of within the field of view;wherein the attenuating includes passing each of the cone beams through a respective filter of varying thickness. 17. The method of claim 13, wherein the attenuating includes passing each of the cone beams through a respective filter of varying thickness. 18. An imaging system comprising: at least two x-ray sources displaced along a z-axis, the at least two x-ray sources configured to alternately emit x-ray beams; an x-ray detector assembly configured to detect the x-ray beams; and an attenuation filter mounted proximate the at least two x-ray sources, the attenuation filter configured to provide different amounts of x-ray attenuation to the x-ray beams along the z-axis. 19. The imaging system of claim 18, wherein the attenuation filter comprises at least one of a substantially triangular shaped portion and a curved portion along the z-axis. 20. The imaging system of claim 18, wherein the attenuation filter provides a greater amount of x-ray attenuation to the x-ray beams proximate a central portion of the attenuation filter along the z-axis and a relatively lesser amount of x-ray attenuation to the x-ray beams proximate outer portions of the attenuation filter along the z-axis. 21. The imaging system of claim 18, wherein the attenuation filter comprises a triangular shaped portion along the z-axis, and wherein a peak of the triangular shaped portion provides greater x-ray attenuation than non-peak portions. 22. The imaging system of claim 18, wherein the attenuation filter comprises one of a triangular shaped portion and a convexly curved portion along a y-z plane and a “U” shaped portion along an x-y plane. 23. The imaging system of claim 18, wherein the x-ray beams partially overlap each other to form an overlapping region within an imaging area, the attenuation filter further configured to provide greater x-ray attenuation within the overlapping region. 24. The imaging system of claim 18, further comprising a processor configured to receive image data based on the x-ray beams, the processor further configured to combine the image data to form a combined image. 25. A method for at least partially compensating for increased x-ray flux from multiple x-ray sources mounted along a z-axis, the method comprising: transmitting x-ray beams alternately from at least two adjacent x-ray sources, the x-ray beams forming an overlapping region within an imaging area; and positioning an attenuation filter between the at least two adjacent x-ray sources and an x-ray detector assembly, the attenuation filter providing different amounts of x-ray attenuation to the x-ray beams along the z-axis. 26. The method of claim 25, wherein the attenuation filter has a higher attenuation coefficient corresponding to the overlapping region and a lower attenuation coefficient corresponding to non-overlapping regions within the imaging area. 27. The method of claim 25, wherein the attenuation filter comprises a central portion and outer portions with respect to the z-axis, the central portion providing a higher level of x-ray attenuation than the outer portions. 28. The method of claim 25, wherein the amount of x-ray attenuation provided is based on a location of the overlapping region. 29. The method of claim 25, wherein the transmitting further comprises transmitting x-ray beams from two other adjacent x-ray sources, the x-ray beams forming a second overlapping region within the imaging area, the attenuation filter further providing different amounts of x-ray attenuation along the z-axis based on the overlapping region and the second overlapping region. 30. The method of claim 25, wherein the attenuation filter comprises at least one substantially triangular shaped portion along the z-axis that has a peak, and the positioning further comprises positioning the peak along the z-axis between two adjacent x-ray sources. 31. A computed tomography (CT) imaging system comprising: at least two x-ray sources aligned along a z-axis; a detector assembly positioned to detect x-rays beams from the at least two x-ray sources, wherein the at least two x-ray sources are configured to alternately emit x-ray beams that partially overlap within an overlapping region of an imaging area, the imaging area located between the at least two x-ray sources and the detector assembly; and an attenuation filter positioned between the at least two x-ray sources and the imaging area, the attenuation filter configured to provide relatively higher x-ray attenuation along the z-axis corresponding to the overlapping region and relatively lower x-ray attenuation along the z-axis corresponding to at least one non-overlapping region of the imaging area. 32. The system of claim 31, wherein the attenuation filter is configured to attenuate the x-ray beams using a substantially triangular shape along the z-axis, and wherein a peak of the triangular shape provides a greatest level of x-ray attenuation. 33. The system of claim 31, further comprising a computer operationally coupled to the at least two x-ray sources and the detector assembly, wherein the computer is configured to receive projection data associated with each of the x-ray beams from the at least two x-ray sources, the computer further configured to combine the projection data into a combined image. 34. The system of claim 31, wherein the attenuation filter comprises a plurality of triangular shaped portions along the z-axis, each of the plurality of triangular shaped portions having a peak, and wherein the peaks of the triangular shaped portions provide greater x-ray attenuation than non-peak portions. 35. The system of claim 31, wherein the attenuation filter comprises at least one of a triangular shaped portion and a curved portion along a y-z plane and a substantially “U” shaped portion along an x-y plane. 36. The system of claim 31, wherein the attenuation filter comprises at least one of aluminum, aluminum alloy, copper and graphite. 37. The system of claim 31, wherein a thickness at a peak of the attenuation filter along the z-axis is between three and four millimeters greater than thicknesses at outer edges of the attenuation filter.