Patent Number: 051608472
Section: claims

1. A dynamic multivane electron arc beam collimator for defining the electron field of an electron beam emitted by a linear accelerator for use in electron arc therapy, said collimator comprising: (a) a plurality of vanes positioned and adapted to define an electron aperture which defines said electron field,  (b) a plurality of vane movement means associated with said vanes for moving said vanes to dynamically define said electron aperture and to thereby dynamically define said electron field, and  (c) a plurality of local controllers to control said vane movement means through distributed processing;  (a) a plurality of vanes positioned and adapted to define an electron aperture which defines said electron field,  (b) a plurality of vane movement means associated with said vanes for moving said vanes to dynamically define said electron aperture and to thereby dynamically define said electron field,  (c) a plurality of local controllers to control said vane movement means, and  (d) a housing; wherein said vanes, vane movement means and local controllers are housed within said housing; wherein said collimator is portable; and wherein said collimator is attachable to and detachable from the head of said linear accelerator.  (a) a plurality of vanes positioned and adapted to define an electron aperture which defines said electron field,  (b) vane movement means for moving said vanes to dynamically define said electron aperture and to thereby dynamically define said electron field, and  (c) a local controller to control said vane movement means and to thereby control movement of said vanes; wherein said vanes, said vane movement means and said local controller are combined to form a unit which is attachable to and detachable from the head of said linear accelerator; and wherein said local controller provides local intelligence to said unit.  (a) a dynamic multivane electron arc beam collimator comprising:  wherein (i), (ii) and (iii) are adapted to provide independent and simultaneous movement of each vane; wherein said vanes are divided into two parallel vane rows to form a plurality of vane pairs; wherein each vane pair is comprised of two opposing vanes which can be moved linearly to dynamically define an opening between said vanes of said pair; and wherein the vane pair openings defined by said vane pairs collectively define said electron aperture.  (b) means for selecting a treatment arc and dividing said treatment arc into a plurality of arc segments defined by reference angles;  (c) means for determining preferred vane pair openings for each arc segment and for representing said preferred vane pair openings as vane position data for each arc segment;  (d) means for monitoring current treatment angle of the linear accelerator during linear accelerator rotation to detect reference angles when encountered by such rotation, and  (e) means for sequentially transmitting to the local controllers of said collimator the vane position data of each arc segment when the reference angle identifying the arc segment is encountered by linear accelerator rotation; 2. A collimator in accordance with claim 1 wherein said vanes are divided into two parallel vane rows to form a plurality of vane pairs; wherein each vane pair is comprised of two opposing vanes which can be moved linearly to dynamically define an opening between said vanes of said pair; and wherein the vane pair openings defined by said vane pairs collectively define said electron aperture. 3. A collimator in accordance with claim 2 wherein the number of said vane pairs ranges from 3 to 71. 4. A collimator in accordance with claim 2 wherein the number of said vane pairs ranges from 5 to 31. 5. A collimator in accordance with claim 2 wherein (a), (b) and (c) are combined to form a unit that is attachable to and detachable from the head of said linear accelerator. 6. A collimator in accordance with claim 2 wherein the number of said vane is an odd number; and wherein the target treatment area is located and centered with respect to the center vane pair. 7. A collimator in accordance with claim 1 wherein each local controller controls one or more of the vane movement means. 8. A collimator in accordance with claim 1 wherein the vane movement means further comprises a vane position monitoring means to monitor the position of the vane associated with the vane movement means. 9. A collimator in accordance with claim 8 wherein the vane position monitoring means is a potentiometer. 10. A collimator in accordance with claim 1 wherein said collimator further comprises a housing for (a), (b) and (c); and wherein said housing is attachable to the head of the linear accelerator and detachable from the head of the linear accelerator. 11. A collimator in accordance with claim 1 wherein said collimator further comprises a noncontact communication means for communication with a remote host controller. 12. A collimator in accordance with claim 11 wherein said noncontact communication means comprises an infra-red transceiver. 13. A collimator in accordance with claim 1 wherein said collimator further comprises a local power source. 14. A collimator in accordance with claim 1 wherein said local controllers are networked as nodes on a common network. 15. A collimator in accordance with claim 1 wherein said vane movement means are local to said vanes. 16. A portable dynamic multivane electron arc beam collimator for defining the electron field of an electron beam emitted by a linear accelerator for use in electron arc therapy, said collimator comprising: 17. A dynamic multivane electron arc beam collimator for defining the electron field of an electron beam emitted by a linear accelerator for use in electron arc therapy, said collimator comprising: 18. A dynamic multivane electron arc beam collimation system for defining the electron field of an electron beam emitted by a linear accelerator for use in electron arc therapy, said collimation system comprising;