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.

An X-ray source (100) comprise a microparticle source (200) configured to generate a particle stream (20) of spatially separated and moving, solid and/or liquid microparticles. The X-ray source (100) also comprises an electron source (300) configured to generate an electron beam (30) of electrons incident onto the particle stream (20) at an interaction region (1) to excite solid and/or liquid microparticles in the interaction region (1) to generate X-rays (10).

The invention relates to a modification arrangement for an X-ray generating device, a modification method, a computer program element for controlling such device and a computer readable medium having stored such computer program element. The modification arrangement comprises a cathode, an anode (2) and modification means, e.g. a modification device. The cathode is configured to provide an electron beam (15). The anode (2) is configured to rotate under impact of the electron beam (15) and is segmented by slits (21) arranged around the anode's circumference. The modification means are configured to modify the electron beam (15) when the electron beam (15) is hitting one of the anode's rotating slits (21).

The present application provides a curved surface array distributed x-ray apparatus, characterized in that, it comprises: a vacuum box which is sealed at its periphery, and the interior thereof is high vacuum; a plurality of electron transmitting units arranged on the wall of the vacuum box in multiple rows along the direction of the axis of the curved surface in the curved surface facing the axis; an anode made of metal and arranged in the axis in the vacuum box which comprises an anode pipe and an anode target surface; a power supply and control system having a high voltage power supply connected to the anode, a filament power supply connected to each of the plurality of the electron transmitting units, a grid-controlled apparatus connected to each of the plurality of electron transmitting units, a control system for controlling each power supply.

The present application provides a curved surface array distributed x-ray apparatus, characterized in that, it comprises: a vacuum box which is sealed at its periphery, and the interior thereof is high vacuum; a plurality of electron transmitting units arranged on the wall of the vacuum box in multiple rows along the direction of the axis of the curved surface in the curved surface facing the axis; an anode made of metal and arranged in the axis in the vacuum box which comprises an anode pipe and an anode target surface; a power supply and control system having a high voltage power supply connected to the anode, a filament power supply connected to each of the plurality of the electron transmitting units, a grid-controlled apparatus connected to each of the plurality of electron transmitting units, a control system for controlling each power supply.

An X-ray imaging method including the following steps is provided. An X-ray source is provided, wherein the X-ray source includes a housing, a cathode, and an anode target. The housing has an end window. The cathode is disposed in the housing, and the anode target is disposed beside the end window. The cathode is caused to provide an electron beam. A portion of the electron beam hits at least a part of areas of the anode target to generate an X-ray and the X-ray is emitted out of the housing through the end window. The X-ray is caused to irradiate an object to generate X-ray image information. An image detector is used to receive the X-ray image information.

An X-ray imaging method including the following steps is provided. An X-ray source is provided, wherein the X-ray source includes a housing, a cathode, and an anode target. The housing has an end window. The cathode is disposed in the housing, and the anode target is disposed beside the end window. The cathode is caused to provide an electron beam. A portion of the electron beam hits at least a part of areas of the anode target to generate an X-ray and the X-ray is emitted out of the housing through the end window. The X-ray is caused to irradiate an object to generate X-ray image information. An image detector is used to receive the X-ray image information.

A multiple X-ray beam X-ray source includes an anode structure and a cathode structure. The anode structure includes a plurality of liquid metal jets providing a plurality of focal lines. The cathode structure provides an electron beam structure that provides a sub e-beam to each liquid metal jet. The liquid metal jets are each hit by the sub e-beam along an electron-impinging portion of the jet circumferential surface that is smaller than half of the circumference of a cross-section of the liquid metal jet.

A multiple X-ray beam X-ray source includes an anode structure and a cathode structure. The anode structure includes a plurality of liquid metal jets providing a plurality of focal lines. The cathode structure provides an electron beam structure that provides a sub e-beam to each liquid metal jet. The liquid metal jets are each hit by the sub e-beam along an electron-impinging portion of the jet circumferential surface that is smaller than half of the circumference of a cross-section of the liquid metal jet.

An x-ray source in which monochromatic x-rays can be produced is provided. A method for producing X-rays and to the use of the x-ray source for x-raying bodies is also provided. A metallic film is arranged in a housing as a target which is bombarded with the electron beam. As a result, the metallic film is excited for emitting monochromatic x-rays, the relatively thin-walled target being modified such that the intended use for producing monochromatic x-rays is no longer possible. Therefore, advantageously, the production device can be pivoted for producing the electron beam as well as being able to wind the target on rollers.