Patent Number: 
Section: claims

1. A charged particle beam irradiation system, comprising:a synchrotron which accelerates an ion beam, wherein the ion beam is extracted from the synchrotron;an irradiation apparatus for irradiating an object to be irradiated with the ion beam introduced from the synchrotron;detection means for measuring an amount of accumulated charge of the ion beam that orbits in the synchrotron immediately before an extraction control period in an operating cycle of the synchrotron; andbeam extraction control means for controlling extraction of the ion beam based on the measurement result of the accumulated beam charge amount so that extraction of a total amount of the ion beam is to be completed with an expiration of an extraction control time, the extraction control time representing a length of the extraction control period of the synchrotron and being set in advance,wherein:the irradiation apparatus is structured to operate at a predetermined irradiation cycle, andthe beam extraction control means sets a value of the integral multiple of the irradiation cycle of the irradiation apparatus for the extraction control time such that an end of the extraction control time occurs at an end of a last irradiation cycle of the irradiation apparatus that occurs within the extraction control time. 2. The charged particle beam irradiation system according to claim 1, whereinthe irradiation apparatus includes a rotating body that has a plurality of periodic structures, each of the periodic structures having a thickness that varies in a rotating direction to thereby vary a level of energy of the ion beam passing therethrough, and irradiates the object to be irradiated with the ion beam that has passed through the periodic structure of the rotating body; andthe irradiation cycle of the irradiation apparatus corresponds to a rotating cycle of each periodic structure of the rotating body. 3. The charged particle beam irradiation system according to claim 1, whereinthe irradiation apparatus includes wobbler scanning magnets and irradiates the object to be irradiated with the ion beam while scanning the object circularly by the wobbler scanning magnets, andthe irradiation cycle of the irradiation apparatus corresponds to a circular scanning cycle of the ion beam by the wobbler scanning magnets. 4. The charged particle beam irradiation system according to claim 1, whereinthe irradiation apparatus includes raster scanning magnets and irradiates each layer in a depth direction of the object to be irradiated with the ion beam while scanning the object zigzag by the raster scanning magnets, andthe extraction control time and a scanning cycle of the ion beam for each layer by the raster scanning magnets are set so as to match with each other. 5. The charged particle beam irradiation system according to claim 1, whereinthe beam extraction control means starts controlling extraction of the ion beam in synchronism with irradiation control performed by the irradiation apparatus after the accumulated beam charge amount has been measured by the detection means. 6. The charged particle beam irradiation system according to claim 1, whereinthe beam extraction control means has set therein a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount in advance; andthe beam extraction control means finds, after the accumulated beam charge amount has been measured by the detection means, a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount, corrects the target beam current intensity pattern data according to the ratio to thereby find a target value of the beam current intensity at that particular point in time, and controls an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity. 7. The charged particle beam irradiation system according to claim 1, whereinthe irradiation apparatus includes a rotating body that has a thickness varying in a rotating direction to thereby vary a level of energy of the ion beam passing therethrough and irradiates the object to be irradiated with the ion beam that has passed through the rotating body, andthe beam extraction control means includes:first means for generating an ON/OFF signal for controlling extraction and extraction stop of the ion beam from the synchrotron during rotation of the rotating body;second means which has set therein a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount in advance, the second means finding a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount after the accumulated beam charge amount has been measured by the detection means, and correcting the target beam current intensity pattern data according to the above-referenced ratio and a ratio of an actual beam extraction time to the extraction control time to thereby find a target value of the beam current intensity at that particular point in time; andthird means for controlling an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity and output timing of the extraction radiofrequency voltage based on the ON/OFF signal. 8. The charged particle beam irradiation system according to claim 7, whereinthe target beam current intensity pattern data is set such that the target value of the beam current intensity decreases with time, andthe second means finds the target value of the beam current intensity that decreases with time in response to the target beam current intensity pattern data. 9. The charged particle beam irradiation system according to claim 1, whereinthe beam extraction control means includes:means for calculating a target value of the current intensity of the beam to be extracted from the synchrotron so that extraction of a total of the ion beam that orbit in the synchrotron is to be completed in time with expiration of the extraction control time;means for measuring a beam current intensity actually extracted from the synchrotron; andmeans for calculating a correction amount of the amplitude of the extraction radiofrequency voltage by using the target value of the beam current intensity and a measured value of the current intensity of the beam actually extracted. 10. The charged particle beam irradiation system according to claim 1, wherein the beam extraction control means includes means for controlling an amplitude of an extraction voltage according to the measurement result of the accumulated beam charge amount. 11. The charged particle beam irradiation system according to claim 1, whereinthe irradiation apparatus includes raster scanning magnets and irradiates each layer in a depth direction of the object to be irradiated with the ion beam while scanning the object zigzag by the raster scanning magnets, andthe extraction control time and a scanning cycle of the ion beam for each layer by the raster scanning magnets are set so as to match with each other. 12. A charged particle beam extraction method for extracting from a synchrotron an ion beam that is accelerated while orbiting in the synchrotron and introducing the ion beam to an irradiation apparatus, the method comprising:a first step of setting in advance an extraction control time that is a length of an extraction control period in an operating cycle of the synchrotron;a second step of measuring an amount of accumulated charge of the ion beam that orbits in the synchrotron immediately before the extraction control period in the operating cycle of the synchrotron; anda third step of controlling the ion beam so that extraction of a total amount of the ion beam is to be completed with an expiration of the extraction control time based on the measurement result of the accumulated beam charge amount,wherein:the irradiation apparatus is structured to operate at a predetermined irradiation cycle, andthe first step sets a value of an integral multiple of the irradiation cycle of the irradiation apparatus for the extraction control time such that an end of the extraction control time occurs at an end of a last irradiation cycle of the irradiation apparatus that occurs within the extraction control time. 13. The charged particle beam extraction method according to claim 12, whereinthe third step starts controlling extraction of the ion beam in synchronism with irradiation control performed by the irradiation apparatus after the accumulated beam charge amount has been measured. 14. The charged particle beam extraction method according to claim 12, whereinthe first step further sets in advance a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount, andthe third step finds, after the accumulated beam charge amount has been measured, a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount, corrects the target beam current intensity pattern data according to the ratio to thereby find a target value of the beam current intensity at that particular point in time, and controls an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity. 15. The charged particle beam extraction method according to claim 12, whereinthe irradiation apparatus includes a rotating body that has a thickness varying in a rotating direction to thereby vary a level of energy of the ion beam passing therethrough and irradiates an object to be irradiated with the ion beam that has passed through the rotating body,the first step further sets in advance a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount, andthe third step comprises:a fourth step of generating an ON/OFF signal for controlling extraction and extraction stop of the ion beam from the synchrotron during rotation of the rotating body;a fifth step of finding, after the accumulated beam charge amount has been measured, a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount, and correcting the target beam current intensity pattern data according to the above-referenced ratio and a ratio of an actual beam extraction time to the extraction control time to thereby find a target value of the beam current intensity at that particular point in time; anda sixth step of controlling an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity and controlling output timing of the extraction radiofrequency voltage based on the ON/OFF signal. 16. The charged particle beam extraction method according to claim 15, whereinthe first step sets the target beam current intensity pattern data such that the target value of the beam current intensity decreases with time, andthe fourth step finds the target value of the beam current intensity that decreases with time in response to the target beam current intensity pattern data. 17. The charged particle beam extraction method according to claim 12, wherein the third step of controlling the ion beam includes controlling an amplitude of an extraction voltage according to the measurement result of the accumulated beam charge amount. 18. A charged particle beam irradiation system, comprising:a synchrotron which accelerates an ion beam, wherein the ion beam is extracted from the synchrotron;an irradiation apparatus for irradiating an object to be irradiated with the ion beam introduced from the synchrotron;a detector which measures an amount of accumulated charge of the ion beam that orbits in the synchrotron immediately before an extraction control period in an operating cycle of the synchrotron; anda beam extraction controller which controls extraction of the ion beam based on the measurement result of the accumulated beam charge amount so that extraction of a total amount of the ion beam is to be completed with an expiration of an extraction control time, the extraction control time representing a length of the extraction control period of the synchrotron and being set in advance,wherein:the irradiation apparatus is structured to operate at a predetermined irradiation cycle, andthe beam extraction controller sets a value of the integral multiple of the irradiation cycle of the irradiation apparatus for the extraction control time such that an end of the extraction control time occurs at an end of a last irradiation cycle of the irradiation apparatus that occurs within the extraction control time. 19. The charged particle beam irradiation system according to claim 18, whereinthe irradiation apparatus includes a rotating body that has a plurality of periodic structures, each of the periodic structures having a thickness that varies in a rotating direction to thereby vary a level of energy of the ion beam passing therethrough, and irradiates the object to be irradiated with the ion beam that has passed through the periodic structure of the rotating body; andthe irradiation cycle of the irradiation apparatus corresponds to a rotating cycle of each periodic structure of the rotating body. 20. The charged particle beam irradiation system according to claim 18, whereinthe irradiation apparatus includes wobbler scanning magnets and irradiates the object to be irradiated with the ion beam while scanning the object circularly by the wobbler scanning magnets, andthe irradiation cycle of the irradiation apparatus corresponds to a circular scanning cycle of the ion beam by the wobbler scanning magnets. 21. The charged particle beam irradiation system according to claim 18, whereinthe beam extraction controller starts controlling extraction of the ion beam in synchronism with irradiation control performed by the irradiation apparatus after the accumulated beam charge amount has been measured by the detector. 22. The charged particle beam irradiation system according to claim 18, whereinthe beam extraction controller has set therein a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount in advance; andthe beam extraction controller finds, after the accumulated beam charge amount has been measured by the detector, a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount, corrects the target beam current intensity pattern data according to the ratio to thereby find a target value of the beam current intensity at that particular point in time, and controls an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity. 23. The charged particle beam irradiation system according to claim 18, whereinthe irradiation apparatus includes a rotating body that has a thickness varying in a rotating direction to thereby vary a level of energy of the ion beam passing therethrough and irradiates the object to be irradiated with the ion beam that has passed through the rotating body, andthe beam extraction controller includes:first means for generating an ON/OFF signal for controlling extraction and extraction stop of the ion beam from the synchrotron during rotation of the rotating body;second means which has set therein a reference value of the accumulated beam charge amount immediately before the extraction control period in the operating cycle of the synchrotron and target beam current intensity pattern data associated with the reference value of the accumulated beam charge amount in advance, the second means finding a ratio of a measured value of the accumulated beam charge amount to the reference value of the accumulated beam charge amount after the accumulated beam charge amount has been measured by the detector, and correcting the target beam current intensity pattern data according to the above-referenced ratio and a ratio of an actual beam extraction time to the extraction control time to thereby find a target value of the beam current intensity at that particular point in time; andthird means for controlling an amplitude of an extraction radiofrequency voltage so as to obtain the target value of the beam current intensity and output timing of the extraction radiofrequency voltage based on the ON/OFF signal. 24. The charged particle beam irradiation system according to claim 23, whereinthe target beam current intensity pattern data is set such that the target value of the beam current intensity decreases with time, andthe second means finds the target value of the beam current intensity that decreases with time in response to the target beam current intensity pattern data. 25. The charged particle beam irradiation system according to claim 18, whereinthe beam extraction controller includes:means for calculating a target value of the current intensity of the beam to be extracted from the synchrotron so that extraction of a total of the ion beam that orbit in the synchrotron is to be completed in time with expiration of the extraction control time;means for measuring a beam current intensity actually extracted from the synchrotron; andmeans for calculating a correction amount of the amplitude of the extraction radiofrequency voltage by using the target value of the beam current intensity and a measured value of the current intensity of the beam actually extracted. 26. The charged particle beam irradiation system according to claim 18, wherein the beam extraction controller controls an amplitude of an extraction voltage according to the measurement result of the accumulated beam charge amount.