To correctly acquire image data of an inspected article by preventing a difference in shade between images caused by a difference in position or sensitivity between sensor elements. An X-ray generation source irradiates an inspection region where an inspected article passes with an X-ray. X-ray detection means receives the X-ray passing through the inspection region using a plurality of sensor elements. Image data generation means generates image data of the inspected article from an output of the X-ray detection means. Incidence condition changing means changes two or more kinds of X-ray incidence conditions common for all of the plurality of sensor elements of the X-ray detection means in a state of absence of the inspected article in the inspection region. Correction data generation means acquires correction data that is needed for making a shade of an image uniform for each incidence condition.

An X-ray spectrometer includes: an excitation source that irradiates a predetermined irradiation region on a surface of a sample with an excitation ray generating a characteristic X-ray; a flat plate analyzing crystal facing the irradiation region; a slit provided between the irradiation region and the analyzing crystal, the slit being parallel to a predetermined crystal plane of the analyzing crystal; a linear sensor including linear detection elements having a length in a direction parallel to the slit are arranged in a direction perpendicular to the slit; and an energy calibration unit that measures two characteristic X-rays in which energy is known by irradiating a surface of a standard sample generating the two characteristic X-rays with the excitation ray from the excitation source, and calibrates the energy of the characteristic X-ray detected by each detection element of the X-ray linear sensor based on the measured energies of the two characteristic X-rays.

Provided are backscatter detection systems and methods implementing sensor arrays comprising flexible scintillators, and associated methods of operations. Specifically, an apparatus for detecting backscatter of a radiation beam formed in response to the radiation beam encountering an object comprises a structure configured to change from a first shape to a second shape. The apparatus further comprises a sensor array which comprises a flexible scintillating panel covering an area of the structure, and configured to conform to the shape of the structure form the first shape to the second shape. The flexible scintillating panel may comprise a plurality of optical fibers enclosed in a semi-rigid casing and coupled to a light detector. The plurality of optical fibers may be arranged in one or more layers. A layer of optical fibers may be arranged in a plurality of clusters or in an interwoven configuration.

This X-ray phase contrast imaging apparatus (100) includes an X-ray source (1), a first grating (3) that forms a self-image, a second grating (4), a detector (5) that detects X-rays, an adjustment mechanism (6), and a controller (7) that controls the adjustment mechanism (6) to adjust a misalignment of the first grating (3) or a misalignment of the second grating (4) based on Moire fringes detected by the detector (5).

The disclosure provides a collimator assembly, comprising at least at least two collimators configured to be moveable relative to each other such that the collimator assembly is switchable between at least two collimation modes; in respective collimation modes, the at least two collimators are superposed with each other in a thickness direction of the collimator assembly, such that the collimator assembly presents different combined patterns for collimating and shielding rays incident onto the collimator assembly and that the collimator assembly has corresponding ray shielding thickness for effectively shielding rays.

An electron diffraction imaging system for imaging the three-dimensional structure of a single target molecule of a sample uses an electron source that emits a beam of electrons toward the sample, and a two-dimensional detector that detects electrons diffracted by the sample and generates an output indicative of their spatial distribution. A sample support is transparent to electrons in a region in which the sample is located, and is rotatable and translatable in at least two perpendicular directions. The electron beam has an operating energy between 5 keV and 30 keV, and beam optics block highly divergent electrons to limit the beam diameter to no more than three times the size of the sample molecule and provide a lateral coherence length of at least 15 nm. An adjustment system adjusts the sample support position in response to the detector output to center the target molecule in the beam.

An apparatus for X-ray measurement, includes an X-ray source, an X-ray detector, an optical inclinometer, and a processor. The X-ray source is configured to generate and direct an X-ray beam to be incident at a grazing angle on a surface of a sample. The X-ray detector is configured to measure X-ray fluorescence emitted from the surface of the sample in response to being excited by the X-ray beam. The optical inclinometer is configured to measure an inclination of the surface of the sample. The processor is configured to calibrate the grazing angle of the X-ray beam based on the measured inclination, and to further fine-tune the grazing angle based on the X-ray fluorescence measured by the X-ray detector.

An aiming system including a first member securable to a device having a point source, a second member selectably rotatable about a first axis relative to the first member, a third member selectably rotatable about a second axis oriented non-parallel to the first axis, and an aiming member having a third axis. The aiming system including the aiming member connected to the third member. A selectable rotation about each of the first axis and the second axis can be independently performed. During the selectable rotation about each of the first axis and the second axis with the aiming member in a first position, the point source, a point on the first axis, a point on the second axis, a point on the third axis are maintained mutually coincident with each other.

An X-ray backscatter indication and detection system, including an object disposed with respect to a target area targeted by X-rays, such that X-rays that backscatter from the target area strike the surface of the object. The surface of the object includes an X-ray sensitive indicator substance that fluoresces with a visible light when contacted by backscattered X-rays.

A method for adjusting a primary side of an X-ray diffractometer wherein the primary side comprises a collimator, X-ray optics, an X-ray source, in particular an X-ray tube, wherein the collimator, the X-ray optics and the X-ray source are mounted directly or indirectly on a base structure, and wherein the orientation and position of the X-ray optics and the position of the X-ray source are adjusted relative to the base structure, wherein the method is characterized in that the orientation and position of the X-ray optics and the position of the X-ray tube relative to the base structure are measured and set at predetermined target values, so that with these set target values, X-ray radiation emanating from the X-ray source and conditioned by the X-ray optics is detectable at the output end of the collimator.