Patent Number: 062158538
Section: claims

1. A method for calibrating a collimator, the method comprising: acquiring a digital image representative of collimator blades aligned relative to a region of interest;  automatically determining a position of at least one collimator blade from the digital image; and  automatically adjusting a position of at least one collimator blade relative to the region of interest.  a communication interface for carrying at least one collimator blade position sensor signal, at least one collimator blade actuator signal, and an image detector signal; and  a central processor, coupled to the communication interface, for automatically determining a position of a collimator blade based on an image detector signal, and for automatically generating a blade activator signal for adjusting a position of a collimator blade toward a desired position relative to the region of interest.  an X-ray detector;  at least one collimator blade located relative to an region of interest;  a detector for detecting a position of the collimator blade;  a blade position controller for moving the collimator blade through at least one of a rotation and a translation; and  a calibrator for determining the position of collimator blades and automatically instructing the blade position controller to move the collimator blade. 2. A method as recited in claim 1, wherein the step of acquiring the digital image comprises acquiring a digital image with a solid state X-ray detector. 3. A method as recited in claim 1, wherein the step of automatically determining position comprises segmenting at least a portion of the digital image into at least one band along an axis, and determining an edge of the collimator blades based on an edge response function. 4. A method as recited in claim 1, wherein the step of automatically determining position comprises fitting a collimator blade edge in the digital image with a linear model. 5. A method as recited in claim 3, wherein the step of automatically determining position further comprises fitting a collimator blade edge in the digital image with a linear model. 6. A method as recited in claim 4, wherein the step of automatically determining position comprises determining a distance from a center of the digital image to a collimator blade edge. 7. A method as recited in claim 1, wherein the step of adjusting a position of at least one collimator blade comprises at least one of translating and rotating at least one collimator blade relative to a reference point. 8. A method as recited in claim 1, wherein the step of adjusting a position of at least one collimator blade comprises adjusting at least one of a width between collimator blades and a centering of the collimator blades in the digital image. 9. A method as recited in claim 1, further comprising the steps of rotating a collimator assembly so that the collimator blades appear in the region of interest, and reversing the rotation after calibration is completed. 10. A method according to claim 1, further comprising the step of iterating the acquiring, determining, and adjusting steps until the collimator blades expose the region of interest within a predetermined tolerance. 11. A collimator calibration subsystem comprising: 12. A collimator calibration subsystem according to claim 11, further comprising at least one sensor and at least one actuator for at least one collimator blade. 13. A collimator calibration subsystem according to claim 11, wherein the communication interface connects to a digital X-ray detector image detector. 14. A collimator calibration subsystem according to claim 11, wherein the processor segments at least a portion of the digital image into at least one band along an axis, averages pixels in each band perpendicular to the axis, and determines edges of the collimator blades using an edge response function. 15. A collimator calibration subsystem according to claim 11, wherein the processor fits a linear model to determine blade edges in the digital image with a linear model. 16. A collimator calibration subsystem according to claim 14, wherein the processor fits a linear model to determine collimator blade edges in the digital image with a linear model. 17. A collimator calibration subsystem according to claim 11, wherein the activator signal induces at least one of translation and rotation of at least one collimator blade using an actuator. 18. A collimator calibration subsystem according to claim 11, wherein the activator signal adjusts at least one of a width between collimator blades and a centering of the collimator blades in the digital image. 19. A collimator calibration subsystem according to claim 11, further comprising a memory coupled to the processor, and wherein the processor stores calibration position information for at least one collimator blade in the memory. 20. A collimator calibration subsystem according to claim 11, wherein the processor iterates the determining and generating steps until the collimator blades expose the region of interest to within a predetermined tolerance. 21. A collimator calibration subsystem according to claim 11, wherein the activator signal induces movement of the collimator blade by a predetermined increment, after which the processor determines a new position of the collimator blade. 22. A collimator calibration subsystem according to claim 11, wherein the processor determines current and destination calibrated positions of the collimator blade, and asserts the activator signal to move the collimator blade from the current position to the destination calibration position. 23. A collimator calibration system comprising: 24. A collimator calibration system of claim 23 wherein the calibrator directs the blade position controller to move the collimator blade by a predetermined increment, after which the calibrator determines a new position of the collimator blade. 25. A collimator calibration system of claim 23, wherein the calibrator calculates current and destination calibrated positions of the collimator blade, and instructs the blade position controller to move the collimator blade from a current position to the destination calibration position. 26. A collimator calibration subsystem according to claim 23, further comprising at least one sensor and at least one actuator for at least one collimator blade. 27. A collimator calibration subsystem according to claim 23, further comprising a communication interface coupled to the X-ray detector, the blade position controller, and the calibrator. 28. A collimator calibration subsystem according to claim 23, wherein the calibrator segments at least at portion of the digital image into at least one band along an axis, averages pixels in each band perpendicular to the axis, and determines edges of the collimator blades using an edge response function. 29. A collimator calibration subsystem according to claim 23, wherein the calibrator fits a linear model to determine blade edges in the digital image with a linear model. 30. A collimator calibration subsystem according to claim 28, wherein the calibrator fits a linear model to determine collimator blade edges in the digital image with a linear model. 31. A collimator calibration subsystem according to claim 23, wherein the blade position controller generates an activator signal that induces at least one of translation and rotation of at least one collimator blade using an actuator. 32. A collimator calibration subsystem according to claim 23, wherein the blade position controller adjusts at least one of a width between collimator blades and a centering of the collimator blades in the digital image. 33. A collimator calibration subsystem according to claim 28, wherein the axis lies in a width direction of the digital image. 34. A collimator calibration subsystem according to claim 23, wherein the calibrator iterates the determining and instructing until the collimator blades expose the region of interest to within a predetermined tolerance.