The radiation detection device according to the present invention comprises: a sample holding unit; an irradiation unit configured to irradiate a sample held by the sample holding unit with radioactive rays; a detection unit configured to detect radioactive rays generated from the sample; a distance calculation unit configured to calculate a distance from a predetermined base point to an irradiated part, which is to be irradiated with radioactive rays, of the sample held by the sample holding unit; a size specification unit configured to specify a size of the irradiated part on the sample based on the calculated distance; and a display unit configured to display the specified size of the irradiated part.

A method of operating a radiation inspection system includes identifying a regulatory region along a predetermined path where public access is restricted based upon criteria other than radiation exposure, measuring a radiation exposure level from a radiation source of the radiation inspection system within the regulatory region, irradiating a target within the regulatory region using the radiation source and without erecting a physical barricade, and determining a restricted area around the radiation source. The restricted area corresponds to an area where a radiation exposure rate exceeds a predetermined threshold. The radiation exposure rate may be determined by the radiation exposure level from the radiation source and a speed of the radiation inspection system. The method may include operating the radiation inspection system to dynamically adjust the restricted area so that it does not extend beyond the regulatory region. The radiation inspection system may be moveable along the predetermined path.

The present invention provides a bright, focused visible light source that is part of a visible light alignment assembly that is coupled to an X-ray generator. The visible light source projects a bright, focused visible light beam from the X-ray generator through a collimator and object or part to be radiographed and to a detector or film, just as a subsequent X-ray beam eventually is. This allows the operator to quickly and easily visually assess the eventual position and coverage or spread of the X-ray beam and align the X-ray generator, collimator, object or part to be radiographed, and/or detector or film, with a minimum of test radiographs.

A system for displaying an image includes at least one x-ray source for emitting radiation, a detector for acquiring the radiation emitted by the radiation source for generating an x-ray image, the detector being disposed opposite the radiation source in relation to an object to be examined, a computer unit for performing computational operations, a display device for displaying x-ray images acquired by the detector and at least one data acquisition unit for acquiring surface information of the object to be examined. The data acquisition unit is disposed on the detector side and the computer unit is configured to correlate the data acquired by the detector-side data acquisition unit with the x-ray image.

An X-ray diffraction measurement method includes an arranging step of arranging a shielding plate and a two-dimensional detector on an outgoing optical axis, and a calculating step of calculating a diffraction profile indicating an X-ray intensity with respect to a diffraction angle of the object to be measured, on the basis of a two-dimensional X-ray image detected by the two-dimensional detector. In the arranging step, the shielding plate is arranged in a manner so that the slit is inclined at least in a direction about the outgoing optical axis with respect to an orthogonal direction which is orthogonal to both the incident optical axis and the outgoing optical axis.

An example method includes obtaining one or more three dimensional computer models that model geometric and material properties of a component, and model beam properties of a beam of radiation to be applied to the component; utilizing the one or more three dimensional computer models to obtain simulated radiation imaging data, which includes simulated elastic scattering data, resulting from a simulated application of the beam having the beam properties on a plurality of discretized samples of the component, and which accounts for sequential interactions of rays of the beam with multiple ones of the plurality of discretized samples; obtaining actual radiation imaging data, which includes actual elastic scattering data, of an output beam pattern caused by application of a non-simulated beam of radiation having the beam properties to the component; and performing at least one of: determining whether an anomaly exists in a crystalline structure of the component based a comparison of the simulated elastic scattering data to the actual elastic scattering data; and modifying the actual radiation imaging data based on the simulated elastic scattering data to at least partially remove the actual elastic scattering data from the actual radiation imaging data. A corresponding system is also disclosed.

The present invention relates to handling misalignment in differential phase contrast imaging. In order to provide an improved handling of misalignment in X-ray imaging systems for differential phase contrast imaging, an X-ray imaging system (10) for differential phase contrast imaging is provided that comprises a differential phase contrast setup (12) with an X-ray source (14), an X-ray detector (16), and a grating arrangement comprising a source grating (18), a phase grating (20) and an analyzer grating (22). The source grating is arranged between the X-ray source and the phase grating, and the analyzer grating is arranged between the phase grating and the detector. Further, the system comprises a processing unit (24), and a measurement system (26) for determining a misalignment of at least one of the gratings. The X-ray source and the source grating are provided as a rigid X-ray source unit (28). The phase grating, the analyzer grating and the detector are provided as a rigid X-ray detection unit (30). The measurement system is an optical measurement system configured to determine a misalignment between the differential phase contrast setup consisting of the X-ray source unit and the X-ray detection unit. Further, the processing unit is configured to provide a correction signal (34) based on the determined misalignment.

An X-ray analyzer is provided with: a sample stage on which a sample is disposed; an X-ray source configured to irradiate the sample with a primary X-ray at a first angle; a detector configured to detect a secondary X-ray generated from the sample; a position adjustment mechanism configured to adjust a relative position between the sample stage and the primary X-ray; a first light source configured to emit a first light beam at a second angle toward a focal position of the primary X-ray or toward a predetermined position; and a second light source configured to emit a second light beam at a third angle toward the focal position or toward the predetermined position, wherein the first light beam and the second light beam are configured to have visibility sufficient for enabling visual distinction.

The distance measurement device includes a ToF type distance measurement camera that measures a distance to a measurement object and a distance to a reference object of which the distance is known, and a processor. The processor calculates a correction coefficient on the basis of a first measurement value that is a measurement value of a distance from the distance measurement camera to the reference object obtained by the distance measurement camera and a known distance from the distance measurement camera to the reference object, and corrects a second measurement value that is a measurement value of a distance from the distance measurement camera to the measurement object obtained by the distance measurement camera or a calculation value calculated using the second measurement value.

A method for quantitatively characterizing a dendrite segregation and dendrite spacing of a high-temperature alloy ingot is disclosed. The method includes preparation and surface treatment of the high-temperature alloy ingot, selection of calibration sample and determination of an element content, establishment of quantitative method for elements in micro-beam X-ray fluorescence spectrometer, quantitative distribution analysis of element components of the high-temperature alloy, quantitative characterization of characteristic element line distribution of high-temperature alloy, and analysis of a characteristic element line distribution map and statistics of a secondary dendrite spacing.