Disclosed is an X-ray generation apparatus for intra-oral X-ray imaging, a guide holder, and an X-ray imaging system comprising the same. The X-ray generation apparatus includes a body and a plurality of X-ray sources disposed in different positions of the body, and configured to irradiate X-rays to a field of view, wherein the body moves along a predetermined trajectory for the field of view.

A portable X-ray system includes an X-ray scanner coupled to a module for processing and visualization of digital signals; and foldable intake and output trays configured to pass an object in and out of the scanner module. The foldable intake and output trays are articulated approximately in their middle. A first drum extends substantially across an entire opening of the scanner tunnel and configured to press down on the object and pull the object inside a scanner tunnel. A second drum extends substantially across an entire opening of the scanner tunnel and configured to press down on the object and pull the object from the scanner tunnel. A radiation shield covers an opening of the scanner tunnel. Sensors detects a type of object to be scanned and to control the first drum according to the type of object to be pulled inside the scanner tunnel.

An information processing apparatus acquires a request for re-imaging or a request for additional imaging. The request for re-imaging is information for requesting imaging for acquiring a second medical image as re-imaging for a previously acquired first medical image. The request for additional imaging is information for requesting imaging for additionally acquiring a third medical image. The information processing apparatus attaches, to the second medical image, information for identifying the first medical image as information for identifying the second medical image when the request for re-imaging is acquired and attaches, to the third medical image, information for identifying the third medical image when the request for additional imaging is acquired.

A computed tomography (CT) image display system (10) includes a mapping unit (32), which receives reconstructed volumetric image data (28) of a subject with values in Hounsfield Units (HU), and a set of reference settings (34), adjusts the set of reference settings (34) to an adjusted set of reference settings (35) according to a pixel-value distribution analysis of the HU values selected according to the reference settings (34), and maps the values in HU to gray scale values according to the adjusted reference settings (35).

A radiation imaging control apparatus comprises an obtainment unit configured to obtain a radiation image captured by an image capturing unit; an extraction unit configured to extract, as a diagnostic image for comparison, a radiation image re-captured by the image capturing unit in a case in which the radiation image is a rejected image; and an output unit configured to output the rejected image and the diagnostic image for comparison to an external apparatus.

A positioning apparatus and a positioning method has a control element and function 40 includes a radiograph acquisition element 41 that acquires radiograph data detected by two radiography systems selected from a group consisting of a flat panel detector, a DRR (Digital Reconstructed Radiograph) generation element 42 that generates DRR in two different directions by virtually performing fluoroscopic projection relative to the 3-dimensional CT data obtained through the network 17, a positioning element 43 that positions a CT to the X-ray fluoroscopic radiograph obtained from two radiography systems, and a displacement distance calculation element 44 that calculates a displacement distance of the tabletop 31 based on the gap between radiographs for improved positioning. The positioning element 43 has a multidimensional optimization element 45 and a 1-dimensional optimization element 46 that optimize parameters relative to rotation and translation of the fluoroscopic projection to maximize an evaluation function that evaluates a matching degree between the DRR and the X-ray fluoroscopic radiograph.

During the generation of a panoramic x-ray recording, the use of semi-transparent x-ray screens allows the patient's x-ray exposure to be reduced when partial x-ray images are created, in spite of relatively large overlapping areas between the partial x-ray images.

A radiographing system includes a mobile terminal configured to store an examination time of a subject that is based on examination-related information about the subject, a radiographing apparatus configured to take a radiation image of the subject based on the examination-related information and to store an imaging time of the radiation image, and an association unit configured to associate the radiation image with the examination-related information based on the imaging time and the examination time.

The present invention provides an X-ray transceiving component for a CT imaging apparatus, comprising one or more bulb devices and a plurality of detector devices. The one or more bulb devices are configured to emit quadrate-tapered or fan-shaped X-ray beams. The plurality of detector devices are configure to receive the quadrate-tapered or fan-shaped X-ray beams emitted by the one or more bulb devices, each of the quadrate-tapered or fan-shaped X-ray beams comprising X-rays passing through a scanning field of view. Note that the plurality of detector devices are configured to receive X-rays passing through different areas within the scanning field of view, the one or more bulb devices are micro-focus bulb devices, and the plurality of detector devices are flat panel detectors or photoelectric coupling detectors. The present invention can greatly improve a resolution of CT imaging, increase imaging efficiency, and realize low-dose diagnosis in the case of ensuring that the scanning field of view is sufficient.

Methods for the correction of drive, tilt and scanning speed errors in imaging systems such as CT machines.