Patent Number: 
Section: claims

1. An x-ray system comprising:an x-ray tube assembly;a collimator forming an aperture;an image detector;a monitor configured to display detected images;means for determining the location of a Region of Interest (ROI) of a patient on said displayed image;a first controller connected with said means for determining the location of a ROI;an image processing unit connected with said image detector, said monitor and said first controller, said image processing unit configured to modify the detected image for display on said monitor according to the image part in said ROI; anda second controller connected with said x-ray tube assembly, said second controller configured to control operating parameters of said x-ray tube,wherein said x-ray tube assembly comprises a cathode, an anode; andmeans for controlling collision location of electrons emitted from said cathode on said anode in reference to said collimator aperture, configured to directing an emitted x-ray beam to said ROI;said first controller configured to calculate a collision location of electrons emitted from said cathode on said anode according to said determined location of said ROI. 2. The x-ray system according to claim 1, wherein said means for determining the location of a ROI comprise an eye tracker. 3. The x-ray system according to claim 1, wherein said means for controlling collision location comprise two electromagnetic devices connected to a current source, said electromagnetic devices configured to produce magnetic fields in the path of electrons flowing from said cathode to said anode, said magnetic fields generally perpendicular to each other;wherein a current level is selected to generate a desired magnetic field in the path of electrons flowing from said cathode to said anode, and wherein a current in each of the electromagnetic devices is set to determine a collision location of the electrons emitted from the cathode on the anode. 4. The x-ray system according to claim 3, further comprising a collimator forming an aperture limiting a solid angle of an x-ray beam emitted from the x-ray tube;wherein the current in each of the electromagnetic devices is set to control a direction of said solid angle of the x-ray beam. 5. The x-ray system according to claim 4, wherein said aperture is movable in a plane generally parallel to a surface of the collimator. 6. The x-ray system according to claim 5, wherein a direction of said solid angle is determined by a combination of the current in each of the electromagnetic devices and the location of said movable aperture. 7. The x-ray system according to claim 5, wherein said first controller is further configured to calculate a location and size of said collimator aperture according to said determined location of the ROI. 8. The x-ray system according to claim 4,wherein said collimator is movable in a plane generally perpendicular to a surface of the collimator andwherein said first controller is further configured to calculate a location of said collimator aperture according to said determined location and size of the ROI. 9. The x-ray system according to claim 1, wherein said means for controlling a collision location comprise two devices for generating an electric field, said devices configured to produce electric fields in the path of the electrons flowing from said cathode to said anode, said electric fields generally perpendicular to each other, said devices connected to an electric potentials source, wherein electric potential levels are determined to generate a desired electric field in the path of electrons flowing from said cathode to said anode, andwherein the electric potential applied to each of the said devices is set to determine a collision location of electrons emitted from the cathode on the anode. 10. The x-ray system according to claim 9, further comprising a collimator forming an aperture limiting a solid angle of an x-ray beam emitted from the x-ray tube, wherein an electric potential applied to each of the devices is set to determine the direction of said solid angle of the x-ray beam. 11. The x-ray system according to claim 10, wherein said aperture is movable in a plane generally parallel to a surface of the collimator. 12. The x-ray system according to claim 11, wherein the direction of said solid angle is determined by a combination of the electric potential applied to each of said devices and a location of said movable aperture. 13. The x-ray system according to claim 10,wherein said collimator is movable in a plane generally perpendicular to a surface of the collimator, andwherein the direction of said solid angle is determined by a combination of the electric potential applied to each of said devices and the location of said movable aperture. 14. An x-ray system comprising:an x-ray tube assembly;a collimator forming an aperture;an image detector;a monitor configured to display detected images;means for determining the location of a Region of Interest (ROI) of a patient on said displayed image;a first controller connected with said means for determining the location of a ROI;an image processing unit connected with said image detector, said monitor and said first controller, said image processing unit configured to modify the detected image for display on said monitor according to the image part in said ROI;a second controller connected with said x-ray tube assembly, said second controller configured to control operating parameters of said x-ray tube; anda collimator forming an aperture limiting a solid angle of an x-ray beam emitted from said x-ray tube;wherein said x-ray tube assembly comprises a cathode, an anode; andmeans for controlling collision location of electrons emitted from said cathode on said anode in reference to said collimator aperture, configured to directing an emitted x-ray beam to said ROI;wherein said means for controlling collision location comprise two electromagnetic devices connected to a current source, said electromagnetic devices configured to produce magnetic fields in the path of electrons flowing from said cathode to said anode, said magnetic fields generally perpendicular to each other;wherein a current level is selected to generate a desired magnetic field in the path of electrons flowing from said cathode to said anode, andwherein a current in each of the electromagnetic devices is set to determine a collision location of the electrons emitted from the cathode on the anode; andwherein the current in each of the electromagnetic devices is set to control a direction of said solid angle of the x-ray beam. 15. The x-ray system according to claim 14, wherein said aperture is movable in a plane generally parallel to a surface of the collimator. 16. The x-ray system according to claim 15, wherein a direction of said solid angle is determined by a combination of the current in each of the electromagnetic devices and the location of said movable aperture. 17. The x-ray system according to claim 15, wherein said first controller is further configured to calculate a location and size of said collimator aperture according to said determined location of the ROI. 18. The x-ray system according to claim 14, wherein said collimator is movable in a plane generally perpendicular to a surface of the collimator; andwherein said first controller is further configured to calculate a location of said collimator aperture according to said determined location and size of the ROI. 19. An x-ray system comprising:an x-ray tube assembly;a collimator forming an aperture;an image detector;a monitor configured to display detected images;means for determining the location of a Region of Interest (ROI) of a patient on said displayed image;a first controller connected with said means for determining the location of a ROI;an image processing unit connected with said image detector, said monitor and said first controller, said image processing unit configured to modify the detected image for display on said monitor according to the image part in said ROI; anda second controller connected with said x-ray tube assembly, said second controller configured to control operating parameters of said x-ray tube,wherein said x-ray tube assembly comprises a cathode, an anode; andmeans for controlling collision location of electrons emitted from said cathode on said anode in reference to said collimator aperture, configured to directing an emitted x-ray beam to said ROI;wherein said means for controlling a collision location comprise two devices for generating an electric field, said devices configured to produce electric fields in the path of the electrons flowing from said cathode to said anode, said electric fields generally perpendicular to each other,said devices connected to an electric potentials source, wherein electric potential levels are determined to generate a desired electric field in the path of electrons flowing from said cathode to said anode; andwherein the electric potential applied to each of the said devices is set to determine a collision location of electrons emitted from the cathode on the anode. 20. The x-ray system according to claim 19, further comprising a collimator forming an aperture limiting a solid angle of an x-ray beam emitted from the x-ray tube, wherein an electric potential applied to each of the devices is set to determine the direction of said solid angle of the x-ray beam. 21. The x-ray system according to claim 20, wherein said aperture is movable in a plane generally parallel to a surface of the collimator. 22. The x-ray system according to claim 21, wherein the direction of said solid angle is determined by a combination of the electric potential applied to each of said devices and a location of said movable aperture. 23. The x-ray system according to claim 20, wherein said collimator is movable in a plane generally perpendicular to a surface of the collimator, andwherein the direction of said solid angle is determined by a combination of the electric potential applied to each of said devices and the location of said movable aperture.