Method of manufacturing radio frequency accelerator, radio frequency accelerator, and circular accelerator system

The invention claimed is: 1. A method of manufacturing a radio frequency accelerator that includes a first-stage linear accelerator for accelerating charged particles injected into the first-stage linear accelerator from an ion source; a second-stage linear accelerator for accelerating a charged particle beam injected into the second-stage linear accelerator from the first-stage linear accelerator through a matching section; a radio frequency power source for generating total radio frequency power to be supplied to the first-stage linear accelerator and the second-stage linear accelerator; and a power distributor for distributively supplying the total radio frequency power supplied from the radio frequency power source to the first-stage linear accelerator and the second-stage linear accelerator, the method of manufacturing the radio frequency accelerator including: a step of setting a value of a power distribution factor R for the power distributor to supply the radio frequency power to the second-stage linear accelerator and a value of a ratio L/ω of a length L of the matching section between an outlet of the first-stage linear accelerator and an inlet of the second-stage linear accelerator to an angular frequency ω of the radio frequency power, so that a charged particle beam is extracted from the second-stage linear accelerator over a range of the total radio frequency power wider than a widest allowable range among allowable total radio frequency power ranges determined for each phase of charged particles on the basis of phase acceptance of the second-stage accelerator. 2. The method of manufacturing the radio frequency accelerator, set forth in claim 1 further including: a first step of calculating, taking values of R as parameters, extraction energy characteristics, which are center-energy characteristics of the charged particle beam extracted from the first-stage linear accelerator, with respect to the total radio frequency power; a second step of calculating, taking values of R as parameters, energy acceptance characteristics for the charged particle beam to be injected into the second-stage linear accelerator with respect to the total radio frequency power; a third step of determining a value of R that matches an extraction energy characteristic calculated in the first step with an energy acceptance characteristic calculated in the second step; a fourth step of calculating, using the value of R determined in the third step, an extraction phase characteristic of the charged particle beam extracted from the first-stage linear accelerator, which is a characteristic of a center phase φ o,1 at an outlet of the first-stage linear accelerator, with respect to the total radio frequency power; a fifth step of calculating, letting v be a velocity of the charged particles in the charged particle beam extracted from the first-stage linear accelerator and using the extraction phase characteristic calculated in the fourth step, inlet phase characteristics, which are characteristics of a center phase φ o,1 +(L/ω)/v of the charged particle beam when the charged particle beam reaches the second-stage linear accelerator from the first-stage linear accelerator, taking values of L/ω as parameters; a sixth step of calculating, using the value of R determined in the third step, a phase acceptance characteristic for the charged particle beam to be injected into the second-stage accelerator with respect to the total radio frequency power; a seventh step of determining a value of L/ω on the basis of an inlet phase characteristic, among the inlet phase characteristics calculated in the fifth step taking values of L/ω as parameters, falling within the phase acceptance characteristic calculated in the sixth step over a range of the total radio frequency power wider than a widest allowable range among the allowable total radio frequency power ranges determined for each phase of charged particles on the basis of phase acceptance of the second-stage accelerator; and an eighth step of setting the power distribution factor R of the power distributor to the value determined in the third step, and setting a length L of the matching section to the value determined in the seventh step. 3. The method of manufacturing the radio frequency accelerator, set forth in claim 2 , wherein a value of L/ω is determined in the seventh step on the basis of the inlet phase characteristic, among the inlet phase characteristics calculated in the fifth step taking values of L/ω as parameters, falling within the phase acceptance characteristic calculated in the sixth step over a total radio frequency power range at least two times wider or more than the widest allowable ranges among the allowable total radio frequency power ranges determined for each phase of charged particles on the basis of phase acceptance of the second-stage accelerator. 4. The method of manufacturing the radio frequency accelerator, set forth in claim 1 further including a step of setting a value of the power distribution factor R for the power distributor to supply the radio frequency power to the second-stage linear accelerator and a value of the ratio L/ω of the matching section length L between the outlet of the first-stage linear accelerator and the inlet of the second-stage linear accelerator to the angular frequency ω of the radio frequency power, so that the charged particle beam is extracted from the second-stage linear accelerator over a total radio frequency power range two times wider or more than the widest allowable range among the allowable total radio frequency power ranges determined for each phase of charged particles on the basis of phase acceptance of the second-stage accelerator. 5. The method of manufacturing the radio frequency accelerator, set forth in claim 1 , wherein the first-stage linear accelerator is a RFQ linac and the second-stage linear accelerator is an APF-IH DTL. 6. The method of manufacturing the radio frequency accelerator, set forth in claim 1 , wherein the power distributor is a resonant-coupler-type power distributor. 7. A radio frequency accelerator comprising: a first-stage linear accelerator for accelerating charged particles injected into the first-stage linear accelerator from an ion source to extract the accelerated charged particles as a charged particle beam; a second-stage linear accelerator for accelerating the charged particle beam injected into the second-stage linear accelerator from the first-stage linear accelerator through a matching section to extract the accelerated charged particle beam; a radio frequency power source for generating total radio frequency power to be supplied to the first-stage linear accelerator and the second-stage linear accelerator; and a power distributor for distributively supplying the total radio frequency power supplied from the radio frequency power source to the first-stage linear accelerator and the second-stage linear accelerator, wherein a value of a power distribution factor R for the power distributor to supply the radio frequency power to the second-stage linear accelerator and a value of a ratio L/ω of a length L of the matching section between an outlet of the first-stage linear accelerator and an inlet of the second-stage linear accelerator to an angular frequency ω of the radio frequency power are set so that the charged particle beam is extracted from the second-stage linear accelerator over a range of the total radio frequency power wider than a widest allowable range among allowable total radio frequency power ranges determined for each phase of charged particles on the basis of phase acceptance of the second-stage accelerator. 8. The radio frequency accelerator set forth in claim 7 , wherein a value of the power distribution