Abstract: A system for x-ray analysis includes at least one x-ray source configured to emit x-rays. The at least one x-ray source includes at least one silicon carbide sub-source on or embedded in at least one thermally conductive substrate and configured to generate the x-rays in response to electron bombardment of the at least one silicon carbide sub-source. At least some of the x-rays emitted from the at least one x-ray source includes Si x-ray emission line x-rays. The system further includes at least one x-ray optical train configured to receive the Si x-ray emission line x-rays and to irradiate a sample with at least some of the Si x-ray emission line x-rays.

Abstract: The purpose of the present invention is to provide a measurement method and a measurement device capable of accurately measuring various metal concentrations of metals included in a solution to be measured containing a plurality of additives and metals.

Abstract: A robotic operating table according to one or more embodiments may include: a patient placement table; a robotic arm comprising a plurality of joints, and having a first end supported on a base and a second end supporting the table; and an operation device comprising a preset position registration setting unit that registers an anesthetization position, a surgical operation position, and an imaging position and sets one of the registered anesthetization, surgical operation, and imaging positions as a movement destination of the table, and a move-operation receiving unit that receives, from a user, a move operation to move the table. When the move-operation receiving unit is operated while one of the registered anesthetization, surgical operation, and imaging positions is set as the movement destination of the table, the robotic arm may move the table to the set one of the registered anesthetization, surgical operation, and imaging positions.

Abstract: An upright posture assisting device for an X-ray inspection of infants, and more particularly to an upright posture assisting device for an X-ray inspection of infants, by which an infant can be X-ray photographed while being safely fixed. The upright posture assisting device for an X-ray inspection of infants includes: a body disposed on the front side of an X-ray detector and having an empty space in the interior thereof; an insertion hole formed on the upper surface of the body such that the legs of an infant are inserted into the insertion hole; and handgrip parts mounted on opposite sides of the upper surface of the body.

Abstract: An X-ray analysis apparatus comprises an X-ray source configured to irradiate a sample with an incident X-ray beam. A first beam mask component is arranged between the X-ray source and the sample. The first beam mask component has a first opening for limiting the size of the incident X-ray beam. When the first beam mask component is in a first configuration, the first opening is arranged in the incident X-ray beam. The first beam mask component further comprises a second opening. When the first beam mask component is in a second configuration, the second opening is arranged in the incident X-ray beam. The second opening does not limit the size of the incident X-ray beam. A controller is configured to control a first beam mask component actuator to change the configuration of the first beam mask component between the first configuration and the second configuration by moving the first beam mask component in a plane intersected by the incident X-ray beam.

Abstract: In one embodiment, an X-ray CT apparatus includes: an X-ray detector equipped with a plurality of detection elements each of which is configured to output an X-ray signal in accordance with X-rays passing through an object; and a scan controller configured to acquire X-ray signals in each of a first mode and a second mode in one scan by switching between the first mode and the second mode, the first mode being a mode of acquiring high-resolution data which are respective X-ray signals outputted from the plurality of detection elements, the second mode being a mode of acquiring normal-resolution data in which X-ray signals outputted from some of the plurality of detection elements are integrated.

Abstract: Disclosed herein is a radiation detector, comprising: a plurality of pixels, and a controller; wherein each pixel is configured to detect radiation emitted from a pulsed radiation source; wherein the pulsed radiation source is configured to emit radiation during a plurality of ON periods and configured not to emit radiation during a plurality of OFF periods; wherein the controller is configured to determine that the pulsed radiation source is at one of the ON periods or at one of the OFF periods; wherein the controller is configured to cause the pixels to integrate signals or not to integrate signals with determination that the radiation source is at one of the ON periods or at one of the OFF periods.

Abstract: An apparatus and method are described using a forward model to correct pulse pileup in spectrally resolved X-ray projection data from photon-counting detectors (PCDs). The forward model represents pulse pileup effects using an integral in which the integrand includes a term that is a function of a count rate, which term is called a spectrum distortion correction function. This correction function can be represented as superposition of basis energy functions and corresponding polynomials of the count rate, which are defined by the polynomial coefficients. To calibrate the forward model, the polynomial coefficients are adjusted to optimize an objective function, which uses calibration data having known projections lengths for the material components of a material decomposition. To determine projection lengths for projection data from a computed tomography scan, the calibrated polynomial coefficients are held constant and the projection lengths are adjusted to optimize an objective function.

Abstract: Embodiments disclose methods and apparatus for managing the provision of radiotherapy treatment. The method includes storing a database of calibration settings for a plurality of components of a first radiotherapy system. The calibration settings may be used by the first radiotherapy system to translate treatment plans into instructions for the plurality of components to carry out. The method further includes deriving from the database allowable ranges of values for the calibration settings. The method also includes receiving from a second radiotherapy system calibration settings for the second radiotherapy system prior to implementation of a treatment plan, comparing the calibration settings for the second radiotherapy system with the derived allowable ranges of values, and generating an alert signal when a subset of the calibration settings for the second radiotherapy system falls outside the allowable range of values.

Abstract: The invention relates to a pulse shaper (18). The pulse shaper (18) comprises an integrator (19) for generating a pulse having a peak amplitude indicative of the energy of a detected photon, a feedback resistor (22), switchable discharge circuitry (23) for discharging the integrator (19), and a peak detector (24) for detecting the peak of the pulse. The pulse shaper is adapted to start the discharge of the integrator by the switchable discharge circuitry based on the detection of the peak and to connect the feedback resistor in parallel to the integrator during a period of the pulse generation and to disconnect the feedback resistor during another period of the pulse generation. The pulse shaper can be such that the generation of the pulse is substantially unhindered by any noticeable concurrent discharging mechanism while, at the same time, the occurrence of energy pedestals can be efficiently avoided.

Abstract: A portable radiation imaging apparatus including: a detection section which includes a plurality of radiation detection elements for accumulating electric charges corresponding to a radiation amount, the radiation detection elements being two-dimensionally arranged; and a control section which controls accumulation of the electric charges in the radiation detection elements and reading of the accumulated electric charges from the radiation detection elements and generates a plurality of frame images of a subject, the electric charges to be accumulated corresponding to the radiation amount of radiation emitted in a pulsed manner by a radiation source and transmitted through the subject, wherein the control section adjusts a synchronization timing between the radiation source and the detection section by using a waveform of radiation emitted by the radiation source, the waveform being obtained by reading electric charges from at least a part of the plurality of radiation detection elements.

Abstract: An x-ray backscattering imaging system creating a backscatter image representing a structure is disclosed. The system includes a drum rotatable about an axis of rotation at a rotational speed, a radioactive source, a container, at least one collimator, at least one light emitting element, and a plurality of backscatter detectors. The radioactive source is connected to the drum and generates x-ray beams. The container houses the radioactive source and is constructed of a material that substantially blocks the x-ray beams generated by the radioactive source. The collimator is defined by the container and has a length and an aperture, where the collimator filters a stream of x-rays generated by the radioactive source such that the x-ray beams traveling substantially parallel with respect to the length of the collimator pass through the aperture. The light emitting element generates visible light and is positioned to direct the visible light into the collimator.

Abstract: A distance sensing assembly and a mobile terminal including the same are provided. The distance sensing assembly includes: an emitter array, a receiver array and a reflective mirror. The emitter array, the receiver array, and the reflective mirror are located below a cover plate of the mobile terminal. An orthographic projection of the reflective mirror on a plane of the cover plate covers at least a portion of a gap between the cover plate and an earpiece of the mobile terminal. Infrared light emitted by the emitter array passes, after being reflected by the reflective mirror, through the gap to be emitted out. The receiver array receives returned infrared light which is reflected, after passing through the gap, by the reflective mirror.

Abstract: According to one embodiment, an X-ray diagnosis apparatus includes an X-ray tube, an input interface, a holding mechanism, an X-ray detector, a display, and processing circuitry. The X-ray tube is configured to radiate X-rays. The input interface is configured to receive an input manual operation of designating at least a direction. The holding mechanism is configured to hold the X-ray tube, and to move the X-ray tube in accordance with the input manual operation, the X-ray tube radiating X-rays during the moving. The X-ray detector is configured to detect X-rays radiated from the X-ray tube and passing through an object, the X-ray detector generating X-ray image data based on the detected X-rays. The display is configured to subsequently display an X-ray image based on the X-ray image data.

Abstract: An X-ray analysis assistance device with an input and operation device 24 for arbitrarily inputting and setting the value of one from among the distance L between a sample S and a two-dimensional detector 2 and the maximum detection range Xmax for X-rays scattered or diffracted by the sample S, and a central processing unit 20 for automatically setting the other setting item on the basis of the value of the one setting item set by the input and operation device 24. Further, the maximum measurement frame Hmax for the X-rays is displayed on a display screen 22 of a display device 21 on the basis of the distance L and maximum detection range Xmax. Additionally, an X-ray detection area A indicating the range within which it is possible for the detection surface of the two-dimensional detector 2 to detect X-rays is displayed on the display screen 22 of the display device 21.

Abstract: An apparatus includes a first multileaf collimator comprising a plurality of pairs of beam-blocking leaves each comprising an end portion. The end portions of beam-blocking leaves of two adjacent pairs are configured to collectively form an aperture when the two adjacent pairs of beam-blocking leaves are closed. The aperture may be sized and shaped to allow a radiation beam to pass through for radiosurgery.

Abstract: Method and systems are disclosed for radiating a moving target inside a heart. The method includes acquiring sequential volumetric representations of an area of the heart and defining a target tissue region and/or a radiation sensitive structure region in 3D for a first of the representations. The target tissue region and/or radiation sensitive structure region are identified for another of the representations by an analysis of the area of the heart from the first representation and the other representation. Radiation beams to the target tissue region are fired in response to the identified target tissue region and/or radiation sensitive structure region from the other representation.

Abstract: A medical imaging apparatus is provided. The medical image apparatus includes an output unit; and a controller configured to control the output unit to display an image obtained by photographing an object and to display, over the image, a top indicator for setting a top limit for an area to be X-rayed and at least one guideline indicating a bottom limit for the area to be X-rayed according to the top indicator and the number of partial photographing operations.

Abstract: A method for delivering radiation treatment may include defining a preliminary trajectory including a plurality of control points. Each control point may be associated with position parameters of a gantry and a couch. The method may also include generating a treatment plan based on the preliminary trajectory by optimizing an intensity and position parameters of a collimator and MLC leaves for each control point. The method may also include decomposing the treatment plan into a delivery trajectory including the plurality of control points. Each of the plurality of control points may be further associated with the optimized intensity, the optimized position parameters of the collimator and the MLC leaves, an output rate, and a motion parameter of each of the gantry, the couch, the collimator, and the MLC leaves. The method may further include instructing a radiation delivery device to deliver the treatment plan according to the delivery trajectory.

Abstract: A radiation therapy system delivers radiation treatment over a 360-degree arc and performs a prepended imaging process, in a single pass, via an extended rotation gantry. While rotating the gantry in one direction about a bore of the radiation system, the radiation system generates multiple images of a target volume disposed in the bore using an imaging X-ray source mounted on the gantry. Then, while continuing to rotate the gantry in the same direction, the radiation system delivers a treatment beam to the target volume using a treatment-delivering X-ray source mounted on the gantry, where the treatment beam is delivered from some or all of a 360-degree arc about the bore. Thus, the prepended imaging process and the delivery of radiation are performed in a single pass of the gantry about a target volume, eliminating the need for a return stroke of the gantry for completion.