Patent Number: 
Section: claims

1. A pre-subject filter assembly for a CT imaging system having a detector assembly and a high frequency electromagnetic energy projection source configured to rotate about a subject during an imaging session, the filter assembly comprising:a beam shaping filter having a body defining multiple filtering profiles, the filter rotatable about an axis of rotation that extends through the body;wherein the beam shaping filter includes a first end and a second end, wherein the body extends between the first end and the second end and comprises a plurality of depressions to define a plurality of body diameters defining the multiple filtering profiles; anda controller to cause rotation of the beam shaping filter about the axis of rotation during an imaging session to dynamically filter high frequency electromagnetic energy projected toward the subject as a function of view angle and independent of voltage applied to the high frequency electromagnetic energy projection source. 2. The pre-subject filter assembly of claim 1 wherein the beam shaping filter has at least two filtering profiles defined orthogonally from one another, wherein the plurality of depressions comprise at least two depressions, wherein the at least two depressions define at least two body diameters defining the at least two filtering profiles defined orthogonally from one another, wherein the at least two depressions are positioned orthogonally from one another. 3. The pre-subject filter assembly of claim 2 wherein a first filtering profile of the at least two filtering profiles defines a maximum filtering profile and a second filtering profile of the at least two filtering profiles defines a minimum filtering profile, and wherein each filtering profile is defined by at least one of a geometry or a composition of the beam shaping filter. 4. The pre-subject filter assembly of claim 3 wherein the beam shaping filter includes a varying filter profile continuum connecting the first filtering profile to the second filtering profile. 5. The pre-subject filter assembly of claim 1 further comprising a pair of end caps, each of which is connected to a respective one of the first and second ends of the beam shaping filter, one end cap having a drive shaft connectable to a motor and the other end cap having a drive shaft connectable to a bearing assembly. 6. The pre-subject filter assembly of claim 1 wherein the beam shaping filter includes a bowtie filter. 7. The pre-subject filter assembly of claim 1 wherein the beam shaping filter includes a first filtering profile that has a maximum point and a minimum point and a second filtering profile has a maximum point and a minimum point, wherein a slope between the maximum point and the minimum point of the first filtering profile is larger than a slope between the maximum point and the minimum point of the second filtering profile, and wherein the controller is further configured to present the first filtering profile in a path of high frequency electromagnetic energy when the subject has a first cross-section and to present the second filtering profile in a path of high frequency electromagnetic energy when the subject has a second cross-section, the first cross-section being narrower and thicker than the second cross-section. 8. The pre-subject filter assembly of claim 1 wherein the plurality of depressions comprises a first depression and a second depression that are formed in the body so as to be acutely or obtusely defined with respect to one another and to define first and second body diameters, of the plurality of body diameters, defining first and second filtering profiles, of the multiple filtering profiles. 9. A CT system comprising:a rotatable gantry having an opening to receive a subject to be scanned;a movable high frequency electromagnetic energy projection source configured to project a high frequency electromagnetic energy beam toward the subject at least two view angles;a movable pre-subject filter having a beam shaping filter that is rotatable about itself relative to an axis of rotation extending through the beam shaping filter during an imaging session, the beam shaping filter having a first end and a second end, the first end having a motor assembly connected thereto and the second end having a bearing assembly connected thereto, such that the motor assembly and bearing assembly, when commanded, cause the beam shaping filter, which has multiple filtering profiles, to rotate about the axis of rotation that is defined by a length of the beam shaping filter that is generally perpendicular to the energy beam that is projected toward the subject;wherein the beam shaping filter includes a body that extends between the first end and the second end and comprises a plurality of depressions to define a plurality of body diameters defining the multiple filtering profiles;a scintillator array having a plurality of scintillator cells wherein each cell is configured to detect high frequency electromagnetic energy passing through the subject;a photodiode array optically coupled to the scintillator array and comprising a plurality of photodiodes configured to detect light output from a corresponding scintillator cell;a data acquisition system (DAS) connected to the photodiode array and configured to receive the photodiode outputs;an image reconstructor connected to the DAS and configured to reconstruct an image of the subject from the photodiode outputs received by the DAS; anda computer programmed to rotate the beam shaping filter about the axis of rotation such that at a first view angle a first filtering profile filters the high frequency electromagnetic energy beam and at a second view angle a second filtering profile filters the high frequency electromagnetic energy beam. 10. The CT system of claim 9 wherein the beam shaping filter includes a bowtie filter designed to reduce high frequency electromagnetic energy dosage to the subject as a function of projection source view angle. 11. The CT system of claim 9 wherein the first filtering profile has a maximum point and a minimum point and the second filtering profile has a maximum point and a minimum point, and wherein a slope between the maximum point and the minimum point of the first filtering profile is larger than that between the maximum point and the minimum point of the second filtering profile. 12. The CT system of claim 11 wherein the computer is further programmed to present the first filtering profile when the high frequency electromagnetic energy source is projecting high frequency electromagnetic energy toward a thickest cross-section of the subject. 13. The CT system of claim 12 wherein the computer is further programmed to present the second filtering profile when the high frequency electromagnetic energy source is projecting high frequency electromagnetic energy toward a thinnest cross-section of the subject. 14. The CT system of claim 9 wherein the first view angle is orthogonal of the second view angle, wherein the plurality of depressions comprise first and second depressions, wherein the first and second depressions define first and second body diameters defining the first and second filtering profiles, wherein the first and second body diameters define the first and second filtering profiles orthogonally from one another, wherein the first and second depressions are positioned orthogonally from one another. 15. The CT system of claim 9 incorporated into at least one of a medical imaging system and a parcel inspection apparatus. 16. A method of reducing x-ray exposure during CT data acquisition comprising the steps of:positioning a subject to be scanned in a scanning bay;positioning a first profile of a multi-profile, beam shaping filter between an x-ray source and the subject when the x-ray source is projecting x-rays at a first view angle, wherein the multi-profile, beam shaping filter includes a first end, a second end, and a body that extends between the first end and the second end and comprises a plurality of depressions to define a plurality of body diameters defining multiple filtering profiles that comprise the first profile and a second profile;projecting x-rays in an x-ray beam toward the subject from the x-ray source at the first view angle;rotating the x-ray source to a second view angle;positioning and rotating the multi-profile, beam shaping filter about an axis of rotation that extends through a length of the multi-profile, beam shaping filter and perpendicular to the x-ray beam such that the second profile of the multi-profile, beam shaping filter is positioned between the x-ray source and the subject when the x-ray source is projecting x-rays at the second view angle; andprojecting x-rays in an x-ray beam toward the subject from the x-ray source at the second view angle. 17. The method of claim 16 wherein the first profile is orthogonal to the second profile, wherein the plurality of depressions comprise first and second depressions, wherein the first and second depressions define first and second body diameters defining the first and second profiles, wherein the first and second body diameters define the first and second profiles orthogonally from one another, wherein the first and second depressions are positioned orthogonally from one another. 18. The method of claim 16 wherein the second profile has a rate change between a maximum filtering point and a minimum filtering point that is less than that between a maximum filtering point and a minimum filtering point of the first profile. 19. The method of claim 18 wherein the first view angle corresponds to a position generally adjacent a side of the subject and the second view angle corresponds to a position generally above the subject. 20. The method of claim 16 further comprising the step of rotating the multi-profile, beam shaping filter about the axis of rotation synchronously with rotation of the x-ray source around the subject.