Patent Number: 
Section: claims

1. A system for reduced dose CT scanning of a subject, the system comprising:(a) a pulse generator configured to be coupled to an X-ray source of a CT scanner, the X-ray source being mounted on gantry so as to rotate within a cylindrical enclosure of the CT scanner;(b) said pulse generator configured to periodically switch off emission of X-rays from the X-ray source, using high speed electromagnetic switching on the order of milliseconds, into the cylindrical enclosure; and(c) a processor configured for controlling said pulse generator and receiving an output from said CT scanner;(d) a non-transitory memory storing instructions executable by the processor;(e) wherein said instructions, when executed by the processor, perform steps comprising:(i) controlling timing of the pulse generator so as to intermittently expose a subject to X-rays from the X-ray source at the pre-specified rotation angles of the gantry;(ii) receiving pulsed images from the CT scanner, the pulsed images corresponding to exposures at said pre-specified rotation angles of said X-ray source within the cylindrical enclosure of the CT scanner;(iii) reconstructing each of said exposures to generate a reconstructed image based on using a K-space Weighted Image Contrast (KWIC) through projection view sharing, wherein a central 2D Fourier Transform (2DFT) space, which determines the image contrast, is sampled by projection views of a time frame of interest, and wherein a peripheral 2DFT space is filled by projection views of time frames neighboring a time frame of interest. 2. The system of claim 1:wherein the pulse generator comprises an off-state to restrict X-rays from being emitted from the X-ray pulse generator source and an on-state configured to allow X-rays to be emitted from the X-ray source into the cylindrical enclosure;wherein the pulse generator is coupled to the X-ray source to electromagnetically shield the X-ray source from emitting X-rays in the off-state; andwherein said instructions when executed by the processor further perform steps comprising timing the on-state of the pulse generator and resulting X-ray exposure at said pre-specified rotation angles of the gantry. 3. The system of claim 2:wherein the X-ray source comprises an anode, a cathode and a griddling electrode therebetween; andwherein the pulse generator is configured to modify a negative potential of the griddling electrode to form an electromagnetic field-based shield so as to prevent electron flow from the cathode the anode, thereby stopping emission of X-rays in the off-state. 4. The system of claim 1, wherein said pre-specified rotation angles comprise a sequence of rotation angles selected from the group of rotation angle schemes consisting of: an angle-bisect scheme, a Golden-ratio scheme, and a Tiny Golden-ratio scheme. 5. An apparatus for reducing X-ray dose to a subject in a CT scanner, the CT scanner comprising an X-ray source being mounted on gantry so as to rotate within a cylindrical enclosure of the CT scanner, and a pulse generator coupled to the X-ray source to periodically switch off emission of X-rays from the X-ray source into the cylindrical enclosure, the apparatus comprising:(a) a computer processor coupled to the CT scanner and the pulse generator; and(b) a non-transitory computer-readable memory storing instructions executable by the computer processor;(c) wherein said instructions, when executed by the computer processor, perform steps comprising:(i) controlling timing of the pulse generator so as to intermittently expose a subject to X-rays from the X-ray source at pre-specified rotation angles of the gantry using high speed electromagnetic switching on the order of milliseconds;(ii) receiving pulsed images from the CT scanner, the pulsed images corresponding to exposures at said pre-specified rotation angles; and(iii) reconstructing each of said exposures to generate a reconstructed image based on using a K-space Weighted Image Contrast (KWIC) through projection view sharing, wherein a central 2D Fourier Transform (2DFT) space, which determines the image contrast, is sampled by projection views of a time frame of interest, and wherein a peripheral 2DFT space is filled by projection views of time frames neighboring a time frame of interest. 6. The apparatus of claim 5:wherein the pulse generator comprises an off-state to restrict X-rays from being emitted from the X-ray pulse generator source and an on-state configured to allow X-rays to be emitted from the X-ray source into the cylindrical enclosure;wherein the pulse generator is coupled to the X-ray source to electromagnetically shield the X-ray source from emitting X-rays in the off-state; andwherein said instructions when executed by the processor perform steps comprising timing the on-state of the pulse generator and resulting X-ray exposure at said pre-specified rotation angles of the gantry. 7. The apparatus of claim 6:wherein the X-ray source comprises an anode, a cathode and a griddling electrode there between therebetween; andwherein said instructions when executed by the processor perform steps comprising controlling said X-ray source to modify a negative potential of the griddling electrode to form an electromagnetic field-based shield so as to prevent electron flow from the cathode the anode, thereby stopping emission of X-rays in the off-state. 8. The apparatus of claim 5, wherein said pre-specified angles of rotation comprise a sequence of rotation angles selected from a group of rotation angle schemes consisting of: an angle-bisect scheme, a Golden-ratio scheme, and a Tiny Golden-ratio scheme. 9. A reduced dose CT scanner for generating CT images of a subject, the CT scanner comprising:(a) an X-ray source disposed within a cylindrical enclosure, wherein the cylindrical enclosure comprising a plurality of detectors configured to detect X-rays emitted from the X-ray source, and in which the X-ray source is mounted on a gantry configured to rotate within the cylindrical enclosure of the CT scanner;(b) a pulse generator coupled to the X-ray source, wherein the pulse generator is configured to periodically switch off emission of X-rays from the X-ray source using high speed electromagnetic switching on the order of milliseconds into the cylindrical enclosure; and(c) a computer processor or server coupled to the pulse generator and the plurality of detectors for receiving pulsed images corresponding to exposures at pre-specified rotation angles of the X-ray source within the cylindrical enclosure;(d) a non-transitory memory storing instructions executable by the processor;(e) wherein said instructions, when executed by the computer processor or server, perform steps comprising:(i) timing of the pulse generator which is configured to intermittently expose a subject to X-rays from the X-ray source at pre-specified rotation angles of the gantry;(ii) receiving pulsed images from the CT scanner, the pulsed images corresponding to exposures at said pre-specified rotation angles;(iii) reconstructing each of said exposures to generate a reconstructed image based on using a K-space Weighted Image Contrast (KWIC) through projection view sharing, wherein a central 2D Fourier Transform (2DFT) space, which determines the image contrast, is sampled by projection views of a time frame of interest, and wherein a peripheral 2DFT space is filled by projection views of time frames neighboring a time frame of interest. 10. The CT scanner of claim 9:wherein the pulse generator is configured with an off-state to restrict X-rays from being emitted from the X-ray pulse generator source and an on-state configured to allow X-rays to be emitted from the X-ray source into the cylindrical enclosure;wherein the pulse generator is coupled to the X-ray source to electromagnetically shield the X-ray source from emitting X-rays in the off-state; andwherein said instructions when executed by the computer processor or server perform steps comprising timing the on-state of the pulse generator and resulting X-ray exposure at said pre-specified rotation angles of the gantry. 11. The CT scanner of claim 10:wherein the X-ray source comprises an anode, a cathode and a griddling electrode therebetween; andwherein the pulse generator is configured to modify a negative potential of the griddling electrode to form an electromagnetic field-based shield so as to prevent electron flow from the cathode the anode, thereby stopping emission of X-rays in the off-state. 12. The CT scanner of claim 9, wherein said pre-specified angles of rotation comprise a sequence of rotation angles selected from group of rotation angle schemes consisting of: an angle-bisect scheme, a Golden-ratio scheme, and a Tiny Golden-ratio scheme. 13. A method for reducing X-ray dose upon a subject in a CT scanner, the CT scanner comprising an X-ray source mounted on gantry so as to rotate within a cylindrical enclosure of the CT scanner and emit of X-rays into the cylindrical enclosure, the method comprising:(a) intermittently exposing a subject within the enclosure to X-rays from the X-ray source using high speed electromagnetic switching on the order of milliseconds at pre-specified rotation angles of the gantry;(b) receiving pulsed images from the CT scanner, the pulsed images corresponding to exposures at said pre-specified rotation angles; and(c) reconstructing each of said exposures to generate a reconstructed image based on using a K-space Weighted Image Contrast (KWIC) through projection view sharing, wherein a central 2D Fourier Transform (2DFT) space, which determines the image contrast, is sampled by projection views of a time frame of interest, and wherein a peripheral 2DFT space is filled by projection views of time frames neighboring a time frame of interest. 14. The method of claim 13:wherein the X-ray source comprises focusing an electron beam on an anode from a cathode for generating said X-rays; andwherein intermittently exposing a subject comprises deflecting the electron beam off the anode using a magnetic field, thereby restricting emission of X-rays from the X-ray source into the cylindrical enclosure to control X-ray exposure to the subject only at said pre-specified rotation angles of the gantry. 15. The method of claim 14, further comprising interposing a griddling electrode between the anode and the cathode of the X-ray source fordeflecting the electron beam off the anode in response to generating sufficient negative potential within the griddling electrode to form an electromagnetic field-based shield so as to prevent electron flow from the cathode the anode, thereby stopping emission of X-rays for pre-specified rotation angles. 16. The method of claim 13, further comprising selecting of said pre-specified angles of rotation in response to utilizing a sequence of rotation angles selected from a group of rotation angle schemes consisting of: an angle-bisect scheme, a Golden-ratio scheme, and a Tiny Golden-ratio scheme.