A radiation imaging apparatus acquires image data by detecting radiation emitted by a radiation generation apparatus, manages a time in the radiation imaging apparatus, generates a synchronization control message to be transmitted to synchronize a time managed by an irradiation control apparatus configured to control radiation irradiation by the radiation generation apparatus with the managed time, and transmits the image data and the synchronization control message, wherein the synchronization control message is transmitted with priority over the image data.

A radiation imaging apparatus includes: a detection unit configured to detect emitted radiation and output radiation image data; a clock control unit that has an internal clock and is configured to control a timing at which the detection unit is driven, based on time information of the internal clock; and a communication unit configured to transmit and receive data through a network, wherein the communication unit, if a communication traffic of the radiation image data is at a threshold or less, transmits the time information to a control apparatus that is connected through the network, and the clock control unit corrects the time information of the internal clock using time information that is a reply from the control apparatus to the time information.

The present invention aims at inhibiting the occurrence of thinning or disconnecting of the bias wiring line in an imaging panel and X-ray imaging device, thereby inhibiting signal delays, signal transmission defects, and the like. A second contact hole electrically connecting an electrode of a photodiode to a bias wiring line penetrates a second interlayer insulating film and photosensitive resin layer. In the second contact hole, an area of a region where the photosensitive resin layer opens is smaller than an area of a region where the second interlayer insulating film opens.

A method for correcting a detector configured to generate object radiographs and an arrangement to implement the method is provided. The method includes the steps of (a) providing the detector having setting values for a gain and offset correction, (b) capturing a plurality of object radiographs of a test object by the detector and generating a reconstructed three-dimensional representation of the test object based on of the object radiographs, (c) determining at least one quality value of the reconstructed three-dimensional representation, repeating the steps (b) and (c) at least once, wherein before the repetition, a parameter set is generated and a measurement sequence is implemented on the basis thereof, at least one setting value for a gain and offset correction of the detector being determined anew based on the measurement sequence; and (e) determining a preferred gain and offset correction based on overall determined quality values.

According to an embodiment, a photon counting CT apparatus includes a scintillator, a photodiode array, a holder, a divider, and an image generator. The scintillator is configured to convert X-rays into light. The array includes first and second pixels. The first pixel includes a photodiode in a first range receiving the light emitted from the scintillator. The photodiode outputs an electrical signal based on the light. The second pixel includes a photodiode in a second range different from the first range. The holder is circuitry configured to hold a value of an electrical signal output by the second pixel. The divider circuitry is configured to count the number of photons of light incident on the first pixel by dividing an integrated value of electrical signals output by the first pixel by the held value. The image generator is circuitry configured to reconstruct an image based on the counted number.

A medical scan comparison system is operable to receive a medical scan via a network and to generate similar scan data. The similar scan data includes a subset of medical scans from a medical scan database and is generated by performing an abnormality similarity function to determine that a set of abnormalities included in the subset of medical scans compare favorably to an abnormality identified in the medical scan. At least one cross-sectional image is selected from each medical scan of the subset of medical scans for display on a display device associated with a user of the medical scan comparison system in conjunction with the medical scan.

An imaging system with integrated magnification stand is described. In an embodiment, the imaging system may include an imaging detector configured to capture an image of human tissue. The imaging system may include a compression paddle situated apart from the imaging detector. A magnification stand of the imaging system may be configured to rotate between a first position and a second position, wherein the magnification stand is situated between the compression paddle and the imaging detector in the first position such that the human tissue can be compressed between the magnification stand and the compression paddle, and wherein the magnification stand is rotated to the second position in which the second position is generally perpendicular to the first position. In this manner, the magnification stand may be stored on the imaging system itself. Other embodiments are described and claimed.

A radiation imaging system is provided. The system includes radiation imaging apparatuses having an arrangement capable of detecting a start of radiation irradiation, and comprising an output unit to output a first signal representing that the apparatus itself has detected a start of irradiation and a receiving unit to receive a second signal representing that another apparatus has detected the start. In a case in which the start of irradiation is detected in a first state, the apparatus transitions to a second state for generating the image data and outputs the first signal. The apparatus in the second state generates the image data regardless of reception of the second signal. In a case in which the second signal is received in the first state, the apparatus transitions to a third state in which power consumption is lower than the first state.

A system and method for obtaining a composite image by combining multiple sub-images are provided. In some embodiments, the method may include retrieving overlapping images corresponding to sub-mages including 3D volume data, generating two-dimensional (2D) projection images and pixel maps based on the overlapping images, performing one or more registrations based on the 2D projection images and the pixel maps, calibrating the sub-images based on the results of the registration(s), and fusing the sub-images to produce a composite image. In some embodiments, the method may include setting a plurality of parameters relating to an X-radiation source or a radiation detector based on a preliminary number of exposures and a preliminary exposure region, controlling, based on at least one of the plurality of parameters, a motion of the X-radiation source or a motion of the radiation detector to capture a plurality of sub-images, and combining the plurality of sub-images.

An aim of the present invention is to improve the conversion efficiency of scintillation light into electric charge by a photoelectric conversion element in an imaging panel of an X-ray imaging system using an indirection conversion scheme. An imaging panel generates images based on scintillation light acquired from X-rays that have passed through a specimen. The imaging panel includes a substrate, thin film transistor, photoelectric conversion element, and reflective layer. The thin film transistor is formed on the substrate. The photoelectric conversion element is connected to the thin film transistor and converts incident scintillation light into electric charge. The entirety of a region of a light-receiving surface of the photoelectric conversion element where the scintillation light is incident overlaps the reflective layer as seen from the incident direction of the scintillation light. The reflective layer may be the drain electrode. Alternatively, the reflective layer may be a reflective electrode that is formed in the same layer as a gate electrode.