Patent Number: 060524308
Section: claims

1. A movable controlled collimator having a plurality of movable collimator leaves, comprising: a plurality of movable leaves configured to delimit a radiation beam path to define a radiation field on an object, said radiation field including a static region and a margin region; and  a control processor configured to move one or more of said plurality of movable leaves from a first predetermined position to a second predetermined position at a constant velocity over said margin region of said field.  generating a radiation beam having a beam path from a radiation source to the patient;  delimiting said beam path by adjusting one or more of a plurality of collimator leaves to define a corresponding radiation field having a static region and a margin region at the patient; and  changing said beam path by moving a predetermined number of said collimator leaves at a constant velocity over said margin region.  a radiation source for generating a radiation beam defining a source beam path to said patient;  a collimator having a plurality of movable leaves configured to delimit said source beam path, to define a radiation field at the patient, said radiation field including a static region and a surrounding region; and  a processor configured to move a predetermined number of the plurality of leaves at a constant velocity within said surrounding region during application of the radiation beam. 2. A movable controlled collimator according to claim 1, wherein said first predetermined position is relatively closer to a center of said beam path than said second predetermined position. 3. A movable controlled collimator according to claim 2, wherein said control processor is configured to begin moving the predetermined number of collimator leaves from said first predetermined position to said second predetermined position a predetermined time after a beginning of the application of the radiation field. 4. A movable controlled collimator according to claim 3, wherein said control processor is configured to move said predetermined number of collimator leaves from said first predetermined position to said second predetermined position upon the beginning of the application of the radiation field. 5. A movable controlled collimator according to claim 3, wherein said control processor is configured to move said predetermined number of collimator leaves a predetermined time after application of a predetermined number of monitor units of radiation, according to the formula: ##EQU3## wherein x is the distance over which the at least one of the plurality of leaves should move and .vertline.DMU/dx.vertline. is the absolute value of a slope of an intensity profile the leaf can deliver. 6. A movable controlled collimator according to claim 1, wherein said second predetermined position is relatively closer to a center of said beam path than said first predetermined position. 7. The radiation treatment apparatus of claim 6, wherein said control processor is configured to move said predetermined number of collimator leaves from an initial position defined by the relation y+z, wherein y is the static field leaf position, and z is the size of the sloped region of the intensity profile. 8. The radiation treatment apparatus of claim 6, wherein said control processor is configured to begin moving said at least one of said collimator leaves from an initial position defined by the relation y+b, wherein y is the static field leaf position, and b is [total MU's/(DMU/dx)]. 9. A method for shaping a cumulative therapeutic radiation exposure to a patient, comprising: 10. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 9, wherein said moving step comprises moving said predetermined number of collimator leaves from a first predetermined position to a second predetermined position, said first predetermined position being relatively closer to a center of said beam path than said second predetermined position. 11. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 10, further comprising waiting to begin moving the predetermined number of collimator leaves from said first predetermined position to said second predetermined position a predetermined time after a beginning of the application of the radiation beam. 12. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 10, further comprising moving said predetermined number of collimator leaves from said first predetermined position to said second predetermined position upon the beginning of the application of the radiation field. 13. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 11, including moving said predetermined number of collimator leaves a predetermined time after application of a predetermined number of monitor units of radiation, according to the formula: ##EQU4## wherein x is the distance over which the at least one of the plurality of leaves should move and .vertline.DMU/dx.vertline. is the absolute value of a slope of an intensity profile the leaf can deliver. 14. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 9, wherein said moving step comprises moving said predetermined number of collimator leaves from a first predetermined position to a second predetermined position, said first predetermined position being relatively farther from a center of said beam path than said second predetermined position. 15. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 14, including moving said predetermined number of collimator leaves from an initial position defined by the relation y+z, wherein y is the static field leaf position, and z is the size of the sloped region of the intensity profile. 16. A method for shaping a cumulative therapeutic radiation exposure to a patient, according to claim 14, including moving said at least one of said collimator leaves from an initial position defined by the relation y+b, wherein y is the static field leaf position, and b is [total MU's/(DMU/dx)]. 17. A radiation treatment apparatus for providing therapeutic radiation to a patient, comprising: