An imaging support apparatus that supports imaging by a radiation imaging apparatus which obtains a plurality of frame images by successively performing a plurality of radiation imaging operations to a subject. The imaging support apparatus includes a hardware processor that determines a number of the frame images to be obtained by the radiation imaging apparatus by analyzing one or more initial frame images, each of the initial frame images being an initial frame image obtained early in the radiation imaging operations by the radiation imaging apparatus.

An imaging support apparatus that supports imaging by a radiation imaging apparatus which obtains a plurality of frame images by successively performing a plurality of radiation imaging operations to a subject. The imaging support apparatus includes a hardware processor that determines a number of the frame images to be obtained by the radiation imaging apparatus by analyzing one or more initial frame images, each of the initial frame images being an initial frame image obtained early in the radiation imaging operations by the radiation imaging apparatus.

In a detection panel, plural pixels which receive X-ray and accumulate electric charge and plural measuring pixels which detect X-ray dose are provided on an imaging surface. The plural measuring pixels are arranged periodically with an interval. In a position facing to the imaging surface, there is a grid where X-ray absorbing sections and X-ray transmitting sections are arranged in a periodic alternating manner in a first direction. Since the arrangement period of the measuring pixels in the first direction is different from a fluctuation period of grid detection signals obtained when the grid is photographed by the detection panel, output values of the plurality of measuring pixels disperse and a fluctuation range of average values is suppressed.

In a detection panel, plural pixels which receive X-ray and accumulate electric charge and plural measuring pixels which detect X-ray dose are provided on an imaging surface. The plural measuring pixels are arranged periodically with an interval. In a position facing to the imaging surface, there is a grid where X-ray absorbing sections and X-ray transmitting sections are arranged in a periodic alternating manner in a first direction. Since the arrangement period of the measuring pixels in the first direction is different from a fluctuation period of grid detection signals obtained when the grid is photographed by the detection panel, output values of the plurality of measuring pixels disperse and a fluctuation range of average values is suppressed.

A system and method for radiochromic film calibration utilizing non-ionizing radiation to achieve controlled and reproducible exposures without the need for ionizing radiation sources or specialized expertise. The system includes a non-ionizing photon source, such as LEDs or laser diodes, emitting ultraviolet or visible light, a mechanical shutter to control exposure duration, and a control unit regulating light emission and shutter operation. A variable optical element of a collimator can be used to shape and direct the light beam for uniform exposure. Precise calibration of the system is performed through a field radiometer for routine verification and periodic cross-validation with ionizing radiation sources.

A system and method for radiochromic film calibration utilizing non-ionizing radiation to achieve controlled and reproducible exposures without the need for ionizing radiation sources or specialized expertise. The system includes a non-ionizing photon source, such as LEDs or laser diodes, emitting ultraviolet or visible light, a mechanical shutter to control exposure duration, and a control unit regulating light emission and shutter operation. A variable optical element of a collimator can be used to shape and direct the light beam for uniform exposure. Precise calibration of the system is performed through a field radiometer for routine verification and periodic cross-validation with ionizing radiation sources.

A method for correcting an X-ray image that is based on imaging during a first time interval and indicates a respective X-ray image value for at least one image point includes receiving a plurality of dark images. A respective dark image is based on image data capturing during a respective subinterval of a second time interval preceding the first time interval, during which no X-rays are irradiated onto an X-ray detector, and indicates a respective dark image value for the respective image point. A respective afterglow value is predicted for the respective image point in the X-ray image, in dependence on the dark image values of a plurality of the dark images for the respective image point. The X-ray image is corrected by ascertaining a respective corrected X-ray image value for the respective image point in dependence on the respective X-ray image value and the respective afterglow value.

A method for correcting an X-ray image that is based on imaging during a first time interval and indicates a respective X-ray image value for at least one image point includes receiving a plurality of dark images. A respective dark image is based on image data capturing during a respective subinterval of a second time interval preceding the first time interval, during which no X-rays are irradiated onto an X-ray detector, and indicates a respective dark image value for the respective image point. A respective afterglow value is predicted for the respective image point in the X-ray image, in dependence on the dark image values of a plurality of the dark images for the respective image point. The X-ray image is corrected by ascertaining a respective corrected X-ray image value for the respective image point in dependence on the respective X-ray image value and the respective afterglow value.