Particle accelerator that produces charged particles having variable energies

What is claimed is: 1. A synchrocyclotron comprising: a voltage source to provide a radio frequency (RF) voltage to a cavity to accelerate particles from a particle source; one or more coils to pass electrical current having one of multiple values and to generate a magnetic field in the cavity corresponding to the electrical current, the magnetic field for causing the particles to move orbitally within the cavity at an energy that corresponds to the electrical current, the magnetic field being at least 4 Tesla; magnetic pole pieces at least partly defining the cavity, the magnetic pole pieces comprising ferromagnetic material; and an extraction channel to receive the particles from the cavity and to output the particles, the particles that are output having an energy that corresponds to the electrical current; wherein the synchrocyclotron is configured to enable setting of the electrical current to one of the multiple values, each of the multiple values corresponding to a different energy at which particles are output from the cavity; wherein the energy of the particles that are output from the cavity is in a range that is between about 100 MeV and about 300 MeV; and wherein the voltage source is configured to sweep the RF voltage over different frequency ranges, each different frequency range corresponding to a different energy at which particles are output from the cavity. 2. The synchrocyclotron of claim 1 , wherein the electrical current comprises a first portion that is fixed and a second portion that is changeable to take on one of multiple values, the second portion of the electrical current being within a range to cause the magnetic field at an extraction radius of the synchrocyclotron to be between about 5% and 35% of a maximum value of the magnetic field. 3. The synchrocyclotron of claim 2 , wherein the magnetic field at the extraction radius is changeable by between about 0.2 Tesla and about 1.4 Tesla. 4. The synchrocyclotron of claim 2 , wherein the magnetic field at the extraction radius is changeable by between about 0.6 and about 4.2 Tesla. 5. The synchrocyclotron of claim 1 , wherein the one or more coils comprises a first set of coils and a second set of coils, the first set being configured to receive a fixed portion of the electrical current, and the second set being configured to receive a portion of the electrical current that is changeable to take on one of multiple values. 6. The synchrocyclotron of claim 5 , wherein the portion of the electrical current that is changeable to take on one of multiple values is within a range that causes the magnetic field at an extraction radius of the synchrocyclotron to change by about 5% and 35% of a maximum value of the magnetic field. 7. The synchrocyclotron of claim 6 , wherein the magnetic field at the extraction radius is changeable by between about 0.2 Tesla and about 1.4 Tesla or between about 0.6 and about 4.2 Tesla. 8. The synchrocyclotron of claim 5 , wherein the magnetic field has a magnitude having a range of about 4 Tesla to about 20 Tesla. 9. The synchrocyclotron of claim 1 , wherein the one or more coils comprises one or more sets of coils, and wherein at least one set of coils is superconducting and comprises between 2 million ampere turns and 10 million ampere turns. 10. The synchrocyclotron of claim 1 , wherein the energy of the particles that are output from the cavity is variable continuously between about 115 MeV and about 250 MeV. 11. The synchrocyclotron of claim 10 , wherein the energy of the particles that are output from the cavity is variable at a rate up to 20 MeV per second. 12. The synchrocyclotron of claim 1 , wherein the energy of the particles that are output from the cavity is variable non-continuously between about 115 MeV and about 250 MeV. 13. The synchrocyclotron of claim 12 , wherein the energy of the particles is variable at a step size of about 10 MeV to about 80 MeV. 14. The synchrocyclotron of claim 13 , wherein each variation of the energy by one step takes less than 30 minutes. 15. The synchrocyclotron of claim 1 , wherein the one or more coils comprises a superconducting coil. 16. The synchrocyclotron of claim 1 , wherein each frequency range comprises a lower boundary and an upper boundary, and wherein the lower boundary is within a range of about 40 MHz to about 250 MHz, and the upper boundary is within a range of about 56 MHz to about 340 MHz. 17. The synchrocyclotron of claim 16 , wherein the lower boundary is within a range of about 73 MHz to about 150 MHz, and the upper boundary is within a range of about 131 MHz to about 196 MHz. 18. The synchrocyclotron of claim 16 , further comprising one or more reactive elements coupled to the voltage source to sweep the RF voltage over a frequency range. 19. The synchrocyclotron of claim 18 , wherein the one or more reactive elements are configured to select the frequency range for a corresponding energy at which the particles are output from the cavity. 20. The synchrocyclotron of claim 19 , wherein the one or more reactive elements comprise a variable capacitor or variable inductor. 21. The synchrocyclotron of claim 1 , wherein the one or more coils comprises a first set of coils and a second set of coils, the first set of coils being superconducting and configured to receive a fixed portion of the electrical current, and the second set of coils being superconducting or nonsuperconducting and configured to receive a portion of the electrical current that is changeable to take on one of multiple values. 22. A proton therapy system comprising: the synchrocyclotron of claim 1 ; and a gantry on which the synchrocyclotron is mounted, the gantry being rotatable relative to a patient position; wherein the particles are protons and the proton therapy system is configured to output the protons from the synchrocyclotron towards the patient position. 23. The synchrocyclotron of claim 1 , further comprising: one or more ferromagnetic rods that are movable relative to the magnetic pole pieces in order to affect a value of the magnetic field. 24. The synchrocyclotron of claim 23 , wherein the one or more ferromagnetic rods are movable within at least one of the magnetic pole pieces. 25. A synchrocyclotron comprising: a voltage source to provide a radio frequency (RF) voltage to a cavity to accelerate particles from a particle source; coils comprising a first set of coils and a second set of coils, the first set of coils to pass a first portion of an electrical current, and the second set of coils to pass a second portion of the electrical current, the first portion being fixed and the second portion being changeable to take on one of multiple values, the coils to generate a magnetic field to cause the particles to move orbitally within the cavity, the magnetic field being at least 4 Tesla; and an extraction channel to receive the particles from the cavity, and to output the particles from the synchrocyclotron. 26. The synchrocyclotron of claim 25 , wherein the second portion of the electrical current is within a range that causes the magnetic field at an extraction radius of the synchrocyclotron to change by between about 5% and 35% of a maximum value of the magnetic field. 27. The synchrocyclotron of claim 26 , wherein the magnetic field at the extraction radius is changeable by between about 0.2 Tesla and about 1.4 Tesla or betwee