A device controller controls an acceleration-related devices and an extraction-related devices of an accelerator for accelerating and extracting a particle beam, in such a way that the controller checks, at a time point when receiving a master clock pulse, that preparation for operating the acceleration-related devices is completed and then commands the acceleration-related devices to operate in accordance with an operation pattern corresponding to a prescribed energy of the particle beam, and commands the acceleration-related devices to operate in accordance with an extracting operation pattern when an extraction enable signal indicating that the particle beam reaches the prescribed energy is turned ON and an extraction-related device setting-status signal indicating that completion of setting the extraction-related devices for the prescribed energy is ON.

There is provided a circular accelerator that accelerates a beam of charged particles circulating in a magnetic field such that a closed orbit for each energy of the beam is eccentric. The circular accelerator includes a beam extraction port for extracting beams of different energies from the closed orbit, a first bending magnet and a second bending magnet that bend the beam extracted from the beam extraction port, and a control unit that controls magnetic field strengths of the first bending magnet and the second bending magnet in accordance with the energy of the extracted beam. When the energy of the extracted beam is a designed maximum energy of the circular accelerator, the control unit excites both the first bending magnet and the second bending magnet to bend the beam.

Embodiments of systems, devices, and methods relate to selecting a raster profile for scanning a proton beam across a target. A raster profile is selected from among the plurality of plurality of possible raster profiles based on a value of a figure of merit. A beam is directed across the target surface to form a pattern that is repeated one or more times at different radial orientations to form a scanning profile. A target temperature is monitored while scanning the beam across the target surface according to the scanning profile. The scanning parameters are changeable to avoid target damaging, to improve thermal performance and to optimize particle loading.

A particle beam apparatus includes: a transport route that guides a particle beam for irradiating an irradiation target to an irradiator; a beam adjustment unit that adjusts a beam size and a beam position of the particle beam; a calculation unit; a storage unit; and an optimization processing unit that searches for a parameter candidate value of the beam adjustment unit, in which the calculation unit adjusts the beam adjustment unit by using the parameter candidate value searched by the optimization processing unit.

A neutron beam source generation system, a neutron beam source stabilization control system, and a neutron beam source generation method are provided. The neutron beam source generation system includes an accelerator, a target, and a calibration module. The accelerator is configured to generate a proton beam. A neutron beam source is generated by irradiating the target with the proton beam. The calibration module includes a pair of electromagnet components, a profile-measuring component, a current-measuring component, and a Faraday cup component. The calibration module uses the pair of electromagnet components to control the distribution of the proton beam according to the profile distribution of the proton beam as measured by the profile-measuring component. The calibration module adjusts the current of the proton beam according to the first current value as measured by the current-measuring component, the second current value as measured by the Faraday cup component, or both.

A target current monitoring device for a boron neutron capture therapy system includes a beam current shaping body and a replaceable target part disposed inside a proton channel of the beam current shaping body, and further includes an automatic conduction detection device independent of the target part, where the automatic conduction detection device includes a contact part and an external current monitoring apparatus electrically connected with the contact part, the contact part is disposed on a moving path of the target part, and the contact part forms a circuit with the external current monitoring apparatus after being in contact with the target part. Since the automatic conduction detection device and target assembly are independently disposed and no hard-wired connection of electric wires exists, the current of the target can be read in real time under full automation, and the automatic replacement, movement and storage of the target can be achieved.