An imaging system includes: an imaging unit that images a subject; and a control unit that enables the imaging unit to perform pre-imaging one or more times, and main imaging one or more times following the pre-imaging; the control unit has an image generating portion that generates a subject image based on one or more taken images in each of the pre-imaging and the main imaging, an interface portion that displays the subject image and accepts a user input for setting at least a region-of-interest, of the region-of-interest and a non-region-of-interest of the subject image, a region setting portion as defined herein, an SN ratio calculating portion as defined herein, and a total light exposure time calculating portion as defined herein; and the control unit enables the imaging unit to perform the main imaging based on the total light exposure time.

An imaging system includes: an imaging unit that images a subject; and a control unit that enables the imaging unit to perform pre-imaging one or more times, and main imaging one or more times following the pre-imaging; the control unit has an image generating portion that generates a subject image based on one or more taken images in each of the pre-imaging and the main imaging, an interface portion that displays the subject image and accepts a user input for setting at least a region-of-interest, of the region-of-interest and a non-region-of-interest of the subject image, a region setting portion as defined herein, an SN ratio calculating portion as defined herein, and a total light exposure time calculating portion as defined herein; and the control unit enables the imaging unit to perform the main imaging based on the total light exposure time.

A detector for imaging and efficiently digitizing a spatial distribution of photon flux includes pixel circuits that compressively encode pixel values generated by integrated analog to digital converters (ADCs). On-pixel digital compression circuits (DCCs) implement compression to increase continuous frame rate by reducing the number of bits per pixel while keeping quantization error below Poisson noise. Several mapping algorithms for photon-counting and charge-integrating detectors and compact digital logic implementations are presented.

A detector for imaging and efficiently digitizing a spatial distribution of photon flux includes pixel circuits that compressively encode pixel values generated by integrated analog to digital converters (ADCs). On-pixel digital compression circuits (DCCs) implement compression to increase continuous frame rate by reducing the number of bits per pixel while keeping quantization error below Poisson noise. Several mapping algorithms for photon-counting and charge-integrating detectors and compact digital logic implementations are presented.

Methods and systems for x-ray and fluoroscopic image capture and, in particular, to a versatile, multimode imaging system incorporating a hand-held x-ray emitter operative to capture digital or thermal images of a target; a stage operative to capture static x-ray and dynamic fluoroscopic images of the target; a system for the tracking and positioning of the x-ray emission; a device to automatically limit the field of the x-ray emission; and methods of use. Automatic systems to determine the correct technique factors for fluoroscopic and radiographic capture, ex-ante.

A radiation imaging apparatus comprising an imaging region where conversion elements used for an imaging operation of obtaining a radiation image corresponding to incident radiation are arranged, detecting portions in each of which a detecting element used to detect a radiation dose entering the imaging region is arranged, and a controller is provided. The controller is configured to perform, before the imaging operation, an offset readout operation of reading out offset signals of the detecting elements from the detecting portions, detect, in the imaging operation, the radiation dose entering the imaging region by using signals output from the detecting elements during irradiation with radiation and the offset signals, and be capable of changing, during a period of the offset readout operation, an order of reading out the offset signals from the detecting portions.

A radiation imaging apparatus comprising an imaging region where conversion elements used for an imaging operation of obtaining a radiation image corresponding to incident radiation are arranged, detecting portions in each of which a detecting element used to detect a radiation dose entering the imaging region is arranged, and a controller is provided. The controller is configured to perform, before the imaging operation, an offset readout operation of reading out offset signals of the detecting elements from the detecting portions, detect, in the imaging operation, the radiation dose entering the imaging region by using signals output from the detecting elements during irradiation with radiation and the offset signals, and be capable of changing, during a period of the offset readout operation, an order of reading out the offset signals from the detecting portions.

A radiation imaging system comprising a radiation imaging apparatus in which pixels are arranged, a radiation source, a display unit, and a controller is provided. The controller causes, during radiation irradiation, the radiation imaging apparatus to repeat a generation operation of generating one image data by causing the pixels to perform an accumulating operation and a readout operation. When it is instructed to terminate the radiation irradiation, the controller causes the radiation source to stop the radiation irradiation in accordance with completion of the accumulating operation and the readout operation of the last row in the generation operation during which it was instructed to terminate the radiation irradiation, and causes the display unit to display an image based on last image data generated by the generation operation during which it was instructed to terminate the radiation irradiation.

A radiation imaging apparatus comprising an imaging region where conversion elements used for an imaging operation of obtaining a radiation image corresponding to incident radiation are arranged, detecting portions in each of which a detecting element used to detect a radiation dose entering the imaging region is arranged, and a controller is provided. The controller is configured to perform, before the imaging operation, an offset readout operation of reading out offset signals of the detecting elements from the detecting portions, detect, in the imaging operation, the radiation dose entering the imaging region by using signals output from the detecting elements during irradiation with radiation and the offset signals, and be capable of changing, during a period of the offset readout operation, an order of reading out the offset signals from the detecting portions.

A radiation imaging apparatus comprising an imaging region where conversion elements used for an imaging operation of obtaining a radiation image corresponding to incident radiation are arranged, detecting portions in each of which a detecting element used to detect a radiation dose entering the imaging region is arranged, and a controller is provided. The controller is configured to perform, before the imaging operation, an offset readout operation of reading out offset signals of the detecting elements from the detecting portions, detect, in the imaging operation, the radiation dose entering the imaging region by using signals output from the detecting elements during irradiation with radiation and the offset signals, and be capable of changing, during a period of the offset readout operation, an order of reading out the offset signals from the detecting portions.