Patent application number | Description | Published |
20090202127 | Method And System For Error Compensation - A method for generating a set of kernels for convolution error compensation of a projection image of a physical object recorded by an imaging system comprises calculating the set of kernels in such a way that for each pixel of the projection image an asymmetric scatter distribution for error compensation is calculated representing a X-ray scatter originating along a ray from an X-ray source to the pixel. | 08-13-2009 |
20100051816 | DETERMINATION OF A SPATIAL GAIN DISTRIBUTION OF A SCINTILLATOR - A method for providing information about a spatial gain distribution of a scintillator for a primary radiation is provided which does not require the irradiation of the scintillator with the primary radiation. The method comprises the step of irradiating the scintillator with a secondary radiation for generating an image of a spatial secondary gain distribution of the scintillator for said second radiation. The spatial secondary gain distribution image corresponds to an image of the spatial primary gain distribution for the primary radiation. In an embodiment of the invention, i.e. in an X-rayimaging device where the primary radiation is X-rayradiation, the invention provides for an accurate calibration of the X-raydetector without irradiating the X-raydetector with X-rayradiation. Rather, irradiation with UV radiation as the secondary radiation provides the desired spatial secondary gain distribution image which can be used for calibration. | 03-04-2010 |
20100067649 | MULTIPLE ROTATION C-ARM - Current C-arm examination devices are not capable of performing 360 degrees rotations. The reason for this is that the cabling which connects the external cabinets to the detector, collimator and x-ray tube does not allow for such a rotation. According to an exemplary embodiment of the present invention, an examination apparatus is provided which has a connection device connecting the external cabinets to the C-arm which is adapted for enabling a rotation of the C-arm of more than 360 degrees. Such a connection device may comprise a storing device for winding up the cable. | 03-18-2010 |
20100290583 | METAL ARTEFACT PREVENTION DURING NEEDLE GUIDANCE UNDER (XPER) CT - The present invention relates to a method and device for preventing metal artefacts computer tomography scans made during biopsy taking, when a metal needle is present in the field of view of a scan. The direction of the metal needle and the direction of the electro-magnetic field are determined in advance. For the determination of the electro-magnetic field a position of a source of the electro-magnetic field a position of a detector are considered. The user may be warned, when the determined direction of the electro-magnetic field and of the direction of the metallic needle correspond to each other. | 11-18-2010 |
20110135053 | CALIBRATION METHOD FOR RING ARTIFACT CORRECTION IN NON-IDEAL ISOCENTRIC 3D ROTATIONAL X-RAY SCANNER SYSTEMS USING A CALIBRATION PHANTOM BASED ROTATION CENTER FINDING ALGORITHM - The present invention refers to 3D rotational X-ray imaging systems for use in computed tomography (CT) and, more particularly, to a fast, accurate and mathematically robust calibration method for determining the effective center of rotation (I) in not perfectly isocentric 3D rotational C-arm systems and eliminating substantially circular ring artifacts (RA) which arise when using such a CT scanner system for acquiring a set of 2D projection images of an object of interest to be three-dimensionally reconstructed. For this purpose, a C-arm based rotational CT scanner comprising at least one radiation detector (D) having an X-radiation sensitive surface exposed to an X-ray beam emitted by at least one X-ray tube (S), each rotating along a non-ideal circular trajectory (TF, T | 06-09-2011 |
20110255657 | SEMICIRCULAR INVERSED OFFSET SCANNING FOR ENLARGED FIELD OF VIEW 3D - A computed tomography acquisition method, an imaging system, a computer readable medium provides laterally displacing a radiation detector ( | 10-20-2011 |