A continuous wave (CW) electron accelerator for the treatment of industrial streams including an electron beam source, a modified high efficiency slot coupled cavity, at least one focusing magnet positioned surrounding the accelerator to contain the beam in the accelerator, an efficient radio frequency power supply means for supplying power of a radio frequency to the cavity to induce a TM01 accelerating mode in the cavity, an electron beam spreader or raster, a fixed magnet array or two-dimensional scanning magnet for deflecting the accelerated beam into a desired shape, and an exit window for extracting the deflected electron beam. The accelerator includes a graded-beta cavity to enable use with a low-power pulsed electron source. The accelerator benefits from a low wall-power loss accelerating cavity that is energized with efficient RF sources, enabling it to be operated in continuous wave mode.

An apparatus may include global control module, the global control module including a digital master clock generator and a master waveform generator. The apparatus may also include a plurality of resonator control modules, coupled to the global control module. A given resonator control module of the plurality of resonator control modules may include a synchronization module, having a first input coupled to receive a resonator output voltage pickup signal from a local resonator, a second input coupled to receive a digital master clock signal from the digital master clock generator, and a first output coupled to send a delay signal to the master waveform generator.

An apparatus may include global control module, the global control module including a digital master clock generator and a master waveform generator. The apparatus may also include a plurality of resonator control modules, coupled to the global control module. A given resonator control module of the plurality of resonator control modules may include a synchronization module, having a first input coupled to receive a resonator output voltage pickup signal from a local resonator, a second input coupled to receive a digital master clock signal from the digital master clock generator, and a first output coupled to send a delay signal to the master waveform generator.

A rotating capacitor is used in a circular accelerator that accelerates a charged particle beam by feeding a first radio frequency to a DC main magnetic field. The rotating capacitor modulates a frequency of the first radio frequency. The rotating capacitor includes a stator electrode and a rotor electrode used for modulating the frequency of the first radio frequency together with the stator electrode. A vacuum seal performs vacuum sealing around a shaft for rotating the rotor electrode. A bearing that supports the shaft is installed on an atmosphere side.

A rotating capacitor is used in a circular accelerator that accelerates a charged particle beam by feeding a first radio frequency to a DC main magnetic field. The rotating capacitor modulates a frequency of the first radio frequency. The rotating capacitor includes a stator electrode and a rotor electrode used for modulating the frequency of the first radio frequency together with the stator electrode. A vacuum seal performs vacuum sealing around a shaft for rotating the rotor electrode. A bearing that supports the shaft is installed on an atmosphere side.

An exciter for a high frequency resonator. The exciter may include an exciter coil inner portion, extending along an exciter axis, an exciter coil loop, disposed at a distal end of the exciter coil inner portion. The exciter may also include a drive mechanism, including at least a rotation component to rotate the exciter coil loop around the exciter axis.

An exciter for a high frequency resonator. The exciter may include an exciter coil inner portion, extending along an exciter axis, an exciter coil loop, disposed at a distal end of the exciter coil inner portion. The exciter may also include a drive mechanism, including at least a rotation component to rotate the exciter coil loop around the exciter axis.

Presented systems and methods facilitate efficient and effective generation and delivery of radiation. In one embodiment, a radiation system includes a patient station, wherein the patient station includes a plurality of accelerator systems, and a microwave generation system configured to generate microwaves for the plurality of accelerators. The plurality of accelerators can be configured to provide substantially simultaneous multiple radiation beams from the plurality of accelerators. In one exemplary implementation, the microwave generation system includes a plurality of radio frequency (RF) sources, wherein respective ones of the plurality of RF sources generate separate microwave signals for corresponding respective ones of the plurality of accelerator systems, and a plurality of modulators, wherein respective ones of the plurality of modulators modulate generation of the separate microwave signals by the respective ones of the plurality of RF sources. The respective ones of the plurality of RF sources and plurality of modulators can be included in a respective plurality of RF chains, wherein respective ones of the plurality of RF chains include a respective circulator and dose rate servo. Multiple radiation beams from the respective plurality of accelerator systems are configured to be transmitted from different orientations.

Presented systems and methods facilitate efficient and effective generation and delivery of radiation. In one embodiment, a radiation system includes a patient station, wherein the patient station includes a plurality of accelerator systems, and a microwave generation system configured to generate microwaves for the plurality of accelerators. The plurality of accelerators can be configured to provide substantially simultaneous multiple radiation beams from the plurality of accelerators. In one exemplary implementation, the microwave generation system includes a plurality of radio frequency (RF) sources, wherein respective ones of the plurality of RF sources generate separate microwave signals for corresponding respective ones of the plurality of accelerator systems, and a plurality of modulators, wherein respective ones of the plurality of modulators modulate generation of the separate microwave signals by the respective ones of the plurality of RF sources. The respective ones of the plurality of RF sources and plurality of modulators can be included in a respective plurality of RF chains, wherein respective ones of the plurality of RF chains include a respective circulator and dose rate servo. Multiple radiation beams from the respective plurality of accelerator systems are configured to be transmitted from different orientations.

Technology is described for an electron gun driver including a half bridge driver circuit and a drive controller. The half bridge driver circuit includes a drive circuit configured to generate a grid drive voltage for a grid connection of an electron gun, and a cutoff circuit configured to generate a grid cutoff voltage for the grid connection of the electron gun, and a gate driver configured to switch between the grid drive voltage and the grid cutoff voltage. The drive controller is configured to generate a pulse input to the drive circuit and cutoff circuit and grid switching signals for the gate driver.