Abstract: A system and method for correcting vignetting distortion in an imaging sensor of a multi-camera flat panel X-Ray detector. A scintillator converts X-Ray radiation generated by an X-Ray source into detectable radiation. A displacement unit generates, during a calibration phase, relative displacement between the X-Ray detector and an X-Ray source at a plane parallel to the scintillator. The imaging sensor acquires, during the calibration phase, a first and a second partial images, the first partial image is acquired before the relative displacement is generated, and the second partial image is acquired after the relative displacement is generated. A relative displacement measurement unit measures the relative displacement. Coefficients of a preliminary inverse vignetting function are calculated based on differences between corresponding pixels of the two partial images.

Abstract: System and method for correcting geometric distortion in a multi-camera flat panel X-Ray detector. A scintillator converts X-Ray radiation generated by an X-Ray source into detectable radiation. Internal markers are placed at known locations adjacent to the scintillator, inside a casing of the detector. External markers placed at known locations outside the casing, adjacent to a cover of the detector. At least one imaging sensor acquires, during the calibration phase, a partial image depicting the external markers and the internal markers. The location of the external markers and the internal markers on the partial X-Ray image is found. A parallax free transformation for correcting geometric distortion based on differences between relation between physical location of the external markers and location of the external markers on the X-Ray image and relation between physical location of the internal markers and location of internal markers on the partial X-Ray image is calculated.

Abstract: System and method for linearization of photometric response of an imaging sensor of a multi-camera flat panel X-Ray detector. The linearization includes acquiring by the imaging sensor, during a linearization phase, at least two images related to detectable radiation radiated by a scintillator in response to X-Ray radiation generated by an X-Ray source at a field of view of the imaging sensor, wherein the intensity of the X-Ray radiation generated by the X-Ray source is different for each of the images, measuring by a light energy measurement unit, substantially simultaneously with the acquiring of each of the images, at least two corresponding levels of energy of the detectable radiation, wherein the light energy measurement unit is substantially linear at the range of operation, and calculating an inverse response function to the imaging sensor based on the images and on the corresponding levels of energy.

Abstract: According to some aspects, a device comprising a plurality of cameras arranged in an array, each of the plurality of cameras producing a signal indicative of radiation impinging on the respective camera, the plurality of cameras arranged such that the field of view of each of the plurality of cameras at least partially overlaps the field of view of at least one adjacent camera of the plurality of cameras, to form a respective plurality of overlap regions, an energy conversion component for converting first radiation impinging on a surface of the energy conversion component to second radiation at a lower energy that is detectable by the plurality of cameras, and at least one computer for processing the signals from each of the plurality cameras to generate at least one image, the at least one processor configured to combine signals in the plurality of overlap regions to form the at least one image is provided.

Abstract: System and method for correcting geometric distortion in a multi-camera flat panel X-Ray detector. A scintillator converts X-Ray radiation generated by an X-Ray source into detectable radiation. Internal markers are placed at known locations adjacent to the scintillator, inside a casing of the detector. External markers placed at known locations outside the casing, adjacent to a cover of the detector. At least one imaging sensor acquires, during the calibration phase, a partial image depicting the external markers and the internal markers. The location of the external markers and the internal markers on the partial X-Ray image is found. A parallax free transformation for correcting geometric distortion based on differences between relation between physical location of the external markers and location of the external markers on the X-Ray image and relation between physical location of the internal markers and location of internal markers on the partial X-Ray image is calculated.

Abstract: System and method for linearization of photometric response of an imaging sensor of a multi-camera flat panel X-Ray detector. The linearization includes acquiring by the imaging sensor, during a linearization phase, at least two images related to detectable radiation radiated by a scintillator in response to X-Ray radiation generated by an X-Ray source at a field of view of the imaging sensor, wherein the intensity of the X-Ray radiation generated by the X-Ray source is different for each of the images, measuring by a light energy measurement unit, substantially simultaneously with the acquiring of each of the images, at least two corresponding levels of energy of the detectable radiation, wherein the light energy measurement unit is substantially linear at the range of operation, and calculating an inverse response function to the imaging sensor based on the images and on the corresponding levels of energy.

Abstract: A system and method for correcting vignetting distortion in an imaging sensor of a multi-camera flat panel X-Ray detector. A scintillator converts X-Ray radiation generated by an X-Ray source into detectable radiation. A displacement unit generates, during a calibration phase, relative displacement between the X-Ray detector and an X-Ray source at a plane parallel to the scintillator. The imaging sensor acquires, during the calibration phase, a first and a second partial images, the first partial image is acquired before the relative displacement is generated, and the second partial image is acquired after the relative displacement is generated. A relative displacement measurement unit measures the relative displacement. Coefficients of a preliminary inverse vignetting function are calculated based on differences between corresponding pixels of the two partial images.

Abstract: Some aspects include a device comprising a plurality of cameras arranged in an array, each producing a signal indicative of radiation impinging on the respective camera, the plurality of cameras arranged such that the field of view of each of the plurality of cameras at least partially overlaps the field of view of at least one adjacent camera of the plurality of cameras, to form a respective plurality of overlap regions, an energy conversion component for converting first radiation impinging on a surface of the energy conversion component to second radiation at a lower energy that is detectable by the plurality of cameras, and at least one computer for processing the signals from each of the plurality cameras to generate at least one image, the at least one processor configured to combine signals in the plurality of overlap regions to form the at least one image.

Abstract: A system, device and a method to perform bilateral filtering using linear convolution by way of an FFT or a recursive sequence method. Proper selection of functions for the photometric and spatial components of a bilateral filter may reduce the computational cost of the bilateral filter while preserving the bilateral filter de-noising and edge detection capabilities. Such functions may reduce the computational cost of a bilateral filter to substantially O(1).

Abstract: According to some aspects, a device comprising a plurality of cameras arranged in an array, each of the plurality of cameras producing a signal indicative of radiation impinging on the respective camera, the plurality of cameras arranged such that the field of view of each of the plurality of cameras at least partially overlaps the field of view of at least one adjacent camera of the plurality of cameras, to form a respective plurality of overlap regions, an energy conversion component for converting first radiation impinging on a surface of the energy conversion component to second radiation at a lower energy that is detectable by the plurality of cameras, and at least one computer for processing the signals from each of the plurality cameras to generate at least one image, the at least one processor configured to combine signals in the plurality of overlap regions to form the at least one image is provided.

Abstract: A system, device and a method to perform bilateral filtering using linear convolution by way of an FFT or a recursive sequence method. Proper selection of functions for the photometric and spatial components of a bilateral filter may reduce the computational cost of the bilateral filter while preserving the bilateral filter de-noising and edge detection capabilities. Such functions may reduce the computational cost of a bilateral filter to substantially O(1).