An X-ray imaging apparatus capable of covering outer peripheral portions of a fixed and moving supporting columns by a cover even when an SID is set to be large in a configuration in which an imaging system is rotated about an axis extending in a horizontal direction. The supporting column mechanism is provided with a fixed supporting column and a moving supporting column. A fixed cover is arranged at the outer peripheral portion of the fixed supporting column. A moving cover which moves together with the moving supporting column is arranged. An intermediate cover movable in the same direction as the moving cover is arranged between the fixed cover and the moving cover. Between the fixed supporting column and the moving cover, a constant force spring as an energizing member for energizing the intermediate cover to the side of the fixed cover is arranged.

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.

This X-ray phase image capturing system (100) includes an X-ray source (1), a plurality of gratings, and a detector (4), a moving mechanism (8), and an image processing unit (5). The image processing unit (5) is configured to generate a phase-contrast image (15) based on a plurality of feature quantities (12) and feature quantities 14 extracted from a plurality of X-ray image sets (R) acquired by performing fringe scanning a plurality of times in a short time.

The radiation detection device includes: a sample holding unit; an optical microscope configured to observe a sample held by the sample holding unit; an irradiation unit that irradiates the sample with radiation; a detection unit that detects radiation generated from the sample; an adjustment unit that adjusts a relationship between a focal position of the optical microscope and a position of the sample such that the optical microscope is focused on one portion of the sample; a change unit that changes a position, on which the optical microscope is to be focused, on the sample; an imaging unit that creates a partial image captured by the optical microscope at the changed position on the sample in a state in which the adjustment unit performs adjustment for focusing; and a sample image creation unit that creates a sample image by combining a plurality of partial images created by the imaging unit.

There is provided an analytical method capable of generating a high resolution spectrum of X-rays with an intended energy. The analytical method is for use in an analytical apparatus having a diffraction grating for spectrally dispersing X-rays emanating from a sample, an image sensor for detecting the spectrally dispersed X-rays, and an incident angle control mechanism for controlling the incident angle of X-rays impinging on the diffraction grating. The image sensor has a plurality of photosensitive elements arranged in the direction of energy dispersion. The analytical method starts with specifying an energy of X-rays to be acquired. The incident angle is adjusted based on the specified energy to bring the focal plane of the diffraction grating into positional coincidence with those one or ones of the photosensitive elements which detect X-rays having the specified energy.

A redundant positioning table device with six or fewer degrees of freedom having four modular legs extended from a base to a table, each legs being with three levels and the same types of joints. In one embodiment, the bottom joint is planar and active, the middle joint is prismatic and passive, and the top joint is spherical and passive. In another embodiment, the bottom joint is prismatic and passive, the middle joint is planar and active, and the top joint is spherical and passive. Fewer than six degrees of freedom is achieved by reducing the number of degrees of freedom of designated joints.

The present invention relates to a device for phase stepping in phase contrast image acquisition, the device (1) comprising: a mobile grating (10); a guiding element (11); a restoring element (12); and a locking element (13); wherein the guiding element (11) is configured to guide the mobile grating (10) between a first position (2) and a second position (3); wherein the restoring element (12) is configured to apply a force to the mobile grating (10); wherein the force is directed from the first position (2) to the second position (3); and wherein the locking element (13) is configured to releasably lock the mobile grating (10) in the first position (2). In an example, during the motion of the mobile grating (10) back to equilibrium, a decoder (11a) for the position of the mobile grating (10) along the guiding element (11) may trigger at least four measurement frames over a period of at least 2*Pi. The invention provides a device (1) for phase stepping in phase contrast image acquisition which provides a fast image acquisition without a significant delay and which reduces positional inaccuracies and which avoids back-lash.

The X-ray imaging device (100) is provided with an X-ray source (1), a plurality of gratings, a moving mechanism (8), and an image processing unit (6). The image processing unit (6) is configured to generate a phase-contrast image (16) by associating a pixel value in each pixel of a subject (T) in a plurality of subject images (10) with phase values of a Moire fringe (30) at each pixel and aligning the pixel of the subject of the same position in the plurality of subject images.

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 image capturing system (100) includes an X-ray source (1), a plurality of gratings, and a detector (4), a moving mechanism (8), and an image processing unit (5). The image processing unit (5) is configured to generate a phase-contrast image (15) based on a plurality of feature quantities (12) and feature quantities 14 extracted from a plurality of X-ray image sets (R) acquired by performing fringe scanning a plurality of times in a short time.