A composite image generation unit of a CPU of a console combines a camera image obtained by capturing an image of a subject located in an irradiation field using a camera and a positioning index image indicating a set position of the subject, which has been set in advance with respect to an in-image cassette position that is the position of the electronic cassette in the camera image, to generate a composite image. In a case in which the in-image cassette position is changed with the movement of the electronic cassette, the composite image generation unit changes a display position of the positioning index image with the change in the in-image cassette position.

A radiation imaging system includes a detection unit configured to detect a dose of radiation irradiation from a radiation source, a first processing unit configured to output a first stop signal when dose information obtained based on first processing for a result of the detection exceeds a threshold, a second processing unit configured to output a second stop signal when dose information obtained based on second processing on a signal having undergone the first processing exceeds a threshold, and a control unit configured to control the radiation source so as to stop the radiation irradiation based on the first stop signal or the second stop signal.

An imaging apparatus for an image intensifier (II) X-ray system includes a camera lens assembly (CLA) configured to cooperate with the II to create an X-ray image, the CLA including an image sensor and a lens. The image sensor is configured to convert received light and generate a digital image. The lens is configured to guide the light from the output surface to the image sensor, the lens having a fixed diaphragm. The CLA includes a diaphragm and/or neutral density filter with a fixed attenuation. A controller is configured to control an amount of amplification of the electric signals or the digital image. The sensor, e.g. CMOS sensor, is configured to amplify the analog electric signals before conversion into the digital image according to an analog gain, and the controller is configured to control the amount of amplification by controlling the analog gain applied by the image sensor.

A radiation imaging apparatus is provided. The apparatus comprises a scintillator configured to convert radiation into light, a sensor panel in which a plurality of pixels each comprising a light detector configured to detect the light is arranged in a two-dimensional array, and a processing unit. The processing unit comprises a signal generating unit configured to output signals indicating intensities of the light detected by the light detector of each of the plurality of pixels, and a detection unit configured to identify a group of pixels each of which outputs a signal of a level exceeding a reference value out of the signals and detect, based on a pattern of the group, pileup in which a plurality of radiation photons is detected as a single radiation photon.

A radiation image capturing apparatus is provided. The radiation image capturing apparatus includes an image capturing unit configured to capture a radiation image. The image capturing unit includes a detection element configured to detect radiation. The radiation image capturing apparatus comprises a processor configured to perform, in accordance with an exposure request from a user, a first reset operation of resetting the detection element, and configured to detect an amount of irradiation of the radiation based on a signal from the detection element after the first reset operation.

There is disclosed an X-ray detector that includes a detection section, an addition rate determination section, an addition section, and a position information storage section in order to enhance the accuracy of interpolation of an output signal from a defective element and suppress artifacts with ease without increasing, for example, the length of processing time, the number of processing circuits, and the amount of interpolation data. The detection section includes a plurality of arrays of detection element groups that are each formed of a plurality of detection elements in correspondence with one pixel. The addition rate determination section determines addition rates for output signals of the detection elements. The addition section calculates the signal value of each pixel of a projection image by adding the output signals of the detection elements belonging to the detection element groups in accordance with the addition rates. The position information storage section stores pixel position information and defective element position information. The pixel position information indicates the positional relationship between the pixel and the detection elements. The defective element position information indicates the position of a defective element. Based on the pixel position information and the defective element position information, the addition rate determination section determines the addition rate for the output signal of the defective element and the addition rate for the output signal of a diagonal detection element positioned symmetrically with respect to the defective element in such a manner that the addition rates are equal and lower than the addition rates for the other detection elements and that the addition rates for the other detection elements are substantially equal.

A method comprising: receiving a radiograph of at least a portion of a patient's body, wherein the radiograph is a digital grayscale image, and wherein each pixel of the grayscale image corresponds to a localized exposure index (EI) value; generating an HSL (Hue-Saturation-Lightness) image from the radiograph, wherein: a hue channel and a saturation channel of the HSL image are generated based on the localized EI values, a luminance channel of the HSL image is generated based on the intensity values of the pixels; and transforming the HSL image to an RGB image which conveys both the portion of the radiograph and the localized EI values.

Circuitry for converting frame data outputted from an obliquely arranged detector, to frame data in a coordinate system for reconstruction is avoided from becoming larger in size and an processing amount is reduced. An X-ray apparatus is provided with a two-dimensional pixel array, the two-dimensional pixel array having a plurality of rectangular pixels, having a predetermined size and outputting an electrical signal in response to an incident X-ray photon. The pixels of the array are arranged in the row and column directions in a first Cartesian coordinate system. The row direction is set obliquely to a scan direction. In this array, when viewing from any one of sides in the scan direction, a pixel group is provided solely or repeatedly, the pixel group being composed of M columns?N pieces pixels (M is a positive integer equal to or larger than 1, N is a positive integer equal to or larger than 2, and M and N have a relationship of prime numbers), the group of pixels providing a quadrangle whose diagonal line is parallel with the scan direction. The frame data, outputted at the constant period from the respective pixels, are converted to frame data in a second Cartesian coordinate system configured in a memory space, the second Cartesian coordinate system having a row direction which is set to accord with the scan direction and a column direction orthogonal to the row direction.

A method and apparatus for detecting and recording an event is disclosed which includes a scintillator located to receive energy from the event. The energy may be x-ray energy from a radiographic source. A mirror is optionally angularly located adjacent the scintillator to redirect or reflect the light into two or more lenses. The two or more lenses have zoom capability to adjust the size of the image and the two or more lenses are arranged as telecentric lenses. A camera receives the light presented from the two or more lenses on an image plane to establish a recorded image while a shutter is presented to selectively control presentation of the light to the camera. The zoom lens allows use of different size scintillators and various CCD cameras to benefit from multiple zoom positions to best capture the image generated by the scintillator.

A radiographic system including a radiation source emitting a radiation beam, a radiation sensor for detecting incident radiation from the radiation beam on a sensor area, at least one collimator arranged between the radiation source and the radiation sensor for masking the radiation beam to irradiate a radiation area on the sensor which is smaller than the sensor area and means for moving the collimator across the radiation beam, whereby the radiation area is moved across the sensor area.