An X-ray computed tomography apparatus images a subject while relatively rotating an X-ray source and an X-ray detector, and the subject. The X-ray computed tomography apparatus includes a theoretical image calculation unit that calculates a theoretical image obtained by irradiating a test object for calibration with X-rays using a geometrical parameter indicating a positional relationship between the X-ray source and the X-ray detector, a correction amount calculation unit that calculates a correction amount based on an amount of deviation between the theoretical image of the test object for calibration and a fluoroscopic image obtained by irradiating the test object for calibration with X-rays, and an image correction unit that corrects a fluoroscopic image of the subject using the correction amount.

An X-ray imaging system including: an X-ray Talbot imaging apparatus which is provided with an object table, an X-ray source, a plurality of gratings, and an X-ray detector side by side in a direction of an X-ray radiation axis, and irradiates the X-ray detector with an X-ray from the X-ray source through an object and the plurality of gratings to obtain a moire image required for forming a reconstruction image of the object; and an object housing inside which the object is housed and an environmental condition independent of an external environment is set, wherein the object housing is provided detachably with respect to the object table.

A method for analyzing a rock sample includes segmenting a digital image volume corresponding to an image of the rock sample, to associate voxels in the digital image volume with a plurality of rock fabrics of the rock sample. The method also includes identifying a set of digital planes through the digital image volume. The set of digital planes intersects with each of the plurality of rock fabrics. The method further includes machining the rock sample to expose physical faces that correspond to the identified digital planes, performing scanning electron microscope (SEM) imaging of the physical faces to generate two-dimensional (2D) SEM images of the physical faces, and performing image processing on the SEM images to determine a material property associated with each of the rock fabrics.

A sample inspection system contains a source of electromagnetic radiation and an apparatus that includes a beam former, a collimator and an energy resolving detector. The beam former is adapted to receive electromagnetic radiation from the source to provide a polygonal shell beam formed of at least three walls of electromagnetic radiation. The collimator has a plurality of channels adapted to receive diffracted or scattered radiation at an angle. The energy resolving detector is arranged to detect radiation diffracted or scattered by a sample upon incidence of the polygonal shell beam onto the sample and transmitted by the collimator.

A variable zoom X-ray CT method can significantly improve resolution for structures with large in-plane dimensions, for example to detect complex structural damage due to low-velocity impact in large thin composite laminate panels. The variable zoom method comprises emitting an X-ray beam from an X-ray source to project a region of interest (ROI) of a specimen within a field of view (FOV) onto a detector. Projections of the ROI are scanned with the detector while rotating the specimen about a rotational axis of a specimen stage and translating the specimen stage along an acquisition trajectory between the X-ray source and the detector. The acquisition trajectory specifies a source-to-object distance (SOD) between the X-ray source and the rotational axis of the specimen stage at each rotation angle of the specimen stage. A reconstruction computer reconstructs a three-dimensional volume of the specimen from the projections scanned by the detector.

Tomographic images are obtained by processing a tilt series of 2D images by aligning and combining images withing a group of neighbor images. The tilt series generally includes sparsely sampled images. Images of the tilt series at tilt angles associated with the sparsely sample images are selected as reference frames, grouped with neighbor images, and the group of images aligned. The aligned images are combined to produce replacement frames and a replacement frame tilt series that can be used for tomographic reconstruction.

A three-dimensional shape registration method includes a step of acquiring three-dimensional CT data of a subject and at least three positioning members, which are acquired by performing X-ray CT imaging on the positioning members together with the subject, a step of measuring relative positions between the subject and each of the positioning members, and a step of performing registration between the subject in the CT data and the subject in three-dimensional design data of the subject based on the CT data, the design data, and information on the relative positions.

An inspection apparatus includes an image generation unit, an image processing unit and an inspection unit. The image generation unit is configured to develop one dimensional transmission signal of an article to be inspected passing through an irradiation line of electromagnetic wave into a two dimensional image on a memory. The image processing unit is configured to perform image processing on a partial image every time the partial image including a part of article to be inspected is generated in the image generation unit. The inspection unit is configured to inspect a quality of the partial image after image processing, based on one or more processing results of the image processing unit.

The present disclosure is related to a Schottky thermal field (TFE) source for emitting an electron beam. Electron optics can adjust a shape of the electron beam before the electron beam impacts a scintillator screen. Thereafter, the scintillator screen generates an emission image in the form of light. An emission image can be adjusted and captured by a camera sensor in a camera at a desired magnification to create a final image of the Schottky TFE source's tip. The final image can be displayed and analyzed to for defects.

A real-time inline digital tomosynthesis system according to an embodiment of the present disclosure includes a subject moving rail configured to move a subject in a preset direction and at a preset speed, a pair of an X-ray generator and an X-ray detector fixedly provided to face each other in a first direction of the subject moving rail, a subject position identifier configured to identify and notify a current position of the subject based on an image or a sensor, and an image reconstructor configured to obtain a plurality of X-ray images having different subject positions through the X-ray detector based on the current position of the subject, and then reconstruct and output the plurality of X-ray images as at least one of a tomographic image for each section and one three-dimensional (3D) image.