The invention relates, in particular, to structures of an arrangement applicable for use in the context of dental or medical X-ray imaging, wherein the arrangement comprises an X-ray detector (15), an X-ray source (14), a light field indicator (141) and a support construction (12) to which the X-ray source (14) construction and the light field indicator (141) construction are mounted. The support construction (12) is configured to enable positioning the X-ray source (14) construction and the light field indicator (141) construction at essentially the same location, so as to when at a given time locating at said essentially same location, to direct a given X-ray irradiation field pattern and visible light field pattern in essentially the same direction towards the X-ray detector (15).

There is provided voltage switching circuitry (100) for an X-ray tube (10). The voltage switching circuitry comprises a plurality of waveform generators (102) connectable to an output (14) of a voltage generator (12) for supplying an operating voltage to the X-ray tube. Each waveform generator is configured to generate a waveform. At least a first said waveform generator is configured to generate a first sinusoidal waveform having a first frequency and at least a second said waveform generator is configured to generate a second sinusoidal waveform having a second frequency. The second frequency differs from the first frequency by at least a factor of two. The voltage switching circuitry is configured to combine the waveforms at the output to switch the operating voltage between at least two different voltage levels. A plurality of the waveform generators (102) further comprise resonators (202, 204) and amplifiers (206) configured to excite resonance in the respective resonators, wherein the voltage switching circuitry (100) is further configured to switch at least one of the amplifiers which is not being used to excite resonance to generate harmonics for reducing over- or undervoltage when switching the opening voltage between the at least two different voltage levels. The voltage switching circuitry further comprises control circuitry configured to control the switching of the amplifiers.

Disclosed herein is a method, comprising: sending one by one M radiation beams (radiation beams (i), i=1, . . . , M) toward a same scene, M being an integer greater than 1; for i=1, . . . , M, capturing with a same image sensor a partial image (i) of the scene using radiation of the radiation beam (i) after the radiation of the radiation beam (i) passes through the scene; and stitching the partial images (i), i=1, . . . , M of the scene resulting in a stitched image of the scene, wherein said stitching is based on relative positions of the M radiation beams with respect to each other.

An imaging system includes a gantry and a compression system coupled to the gantry and rotatable relative to the gantry. The compression system includes a compression paddle, a support platform, and an x-ray receptor disposed below the support platform. An x-ray tube head is coupled to the gantry and includes an x-ray source and a light source. The x-ray tube head is independently rotatable relative to the gantry and the compression system. The light source is configured to generate at least a first light type and a different second light type directed towards the support platform. The second light type being mapped to an x-ray field of the x-ray source, and the generated second light type is based on a tilt angle of the x-ray tube head relative to the support platform and a compression force of the compression paddle.

Interstitial brachytherapy is a cancer treatment in which radioactive material is placed closely to the target tissue of the affected site using an afterloader (HDR-brachytherapy) or manually (LDR- and PDR-brachytherapy). For HDR-brachytherapy, the accuracy of this placement is calibrated using an external reference system that locates the radioactive material according to the radiation levels measured at locations around the source. At each of these locations, a scintillator produces light when irradiated by the radioactive material. This light is proportional to the level of radiation at each location. The light produced by each scintillator is converted to an electrical signal that is proportional to the light and the radiation level at each location. The radioactive material is located according to the plurality of electrical signals.

Disclosed is a ceramic shielding apparatus including at least one shield made of a ceramic material and provided inside or outside an X-ray tube to shield radiation; and supports configured to support the shield. According to such a configuration, disadvantages of conventional shielding materials such as lead can be addressed, so that a shield apparatus having excellent shielding properties while being harmless to the human body can be provided.

An X-ray system is disclosed, including an electron-impact X-ray source configured to generate an X-ray beam; a radiation-shielded housing having an X-ray outlet port; an X-ray optical element arranged within the radiation-shielded housing configured to direct the X-ray beam toward the outlet port; a shutter arranged at the outlet port, the shutter being movable between an open position at which X-ray output through the outlet port is allowed, and a closed position at which X-ray output through the outlet port is prevented; and a detector arranged to detect X-ray radiation from the X-ray source directed towards the outlet port, wherein the detector is configured to detect X-ray radiation within a first energy range. A corresponding method of operating an X-ray system is also disclosed.

Collimation device for an X-ray detection system, the collimation device comprising: a collimator comprising a substantially planar support made of a material with partial or zero radiotransparency, the support being rotatably movable about an axis of rotation (Δ) which passes through the support and which is perpendicular to a first face of the support which acts as an X-ray plane of incidence referred to as the main plane of the support (P), the support (D) being provided on the first face with a slit which is completely transparent to X-rays and which is configured to generate an X-ray flow when the collimator is exposed to an X-ray source, the slit extending longitudinally in the main plane of the support along an axis located at a non-zero distance (d) from the axis of rotation (Δ), the slit extending through the entire thickness of the support.

The invention relates, in particular, to structures of dental and medical cone beam computed tomography (CBCT) imaging apparatus. The basic construction of the apparatus includes a substantially vertically extending frame part (11) which supports via a horizontally extending support construction (12) the X-ray imaging means (14, 15) of the apparatus. The apparatus includes a patient support structure (18) which extends substantially in parallel with and is essentially of the same length as the substantially vertically extending frame part (11).

A system and method relating to a radiation based imaging are provided. The system may include a radiation source, a detector, a first grid, and a second grid. The detector may include a plurality of detector cells. The first grid may be located between the radiation source and the detector and include a plurality of first radiation transmitting sections. The second grid may be located between the first grid and the detector and include a plurality of second radiation transmitting sections. An extending direction of at least one of the plurality of first radiation transmitting sections may be different from that of at least one of the plurality of second radiation transmitting sections.