Abstract: A method is disclosed for determining a configuration for a computer tomograph for the purpose of error diagnosis, a module, a computer tomograph and a system of appropriate design. The computer tomograph includes a multiplicity of detector modules. In at least one embodiment, a respective detector module is designed to have an identification device which is intended to provide a signature, the signature being uniquely associated with the respective module. The detector module transmits the measurement data it captures and its signature. The digital, electronic signature allows remote maintenance of the computer tomograph.

Abstract: A radiation detector is disclosed for the detection of ionizing radiation, preferably in a medical diagnosis and/or therapy system, having at least one detector element which is at least partially enclosed by an encapsulation compound. The encapsulation compound at least partially reflects light which is produced during the absorption of the ionizing radiation in the at least one detector element. Further, the detection of the radiation is carried out indirectly by detection of the generated light, wherein the encapsulation compound is made of a multicomponent mixture which converts compounds produced because of radiation, which generate color changes of the encapsulation compound, at least partially into colorless nonabsorbing compounds.

Abstract: A method and a control device are for controlling the temperature of a detector system inside a computed tomography unit. The CT unit includes a rotatable gantry with a gantry housing in which both an X-ray tube and the detector system are located. The detector system is arranged, in turn, inside a detector housing. The air temperature is set in the gantry housing via a temperature-controlled air circulation. The temperature of the ambient air of the detector housing is set by a control system that uses the temperature of the detector system as controlled variable.

Abstract: A detector is disclosed, in particular for X-radiation. The detector includes an array of photodiodes, each respectively corresponding to a pixel with regard to size of their photosensitive receiving surface. Each photodiode is subdivided in the same way into at least two sub-photodiodes. Further, each photodiode includes at least one electric switch such that only one or all the sub-photodiodes of the photodiode are connectable to an evaluation circuit.

Abstract: An adapter is disclosed for a detector including a plurality of detector modules. A method is further disclosed for carrying out faultfinding on the detector including such an adapter. It is possible for an electrical cross-connection to be produced between at least one first detector module and a second slot on a printed circuit board, and between a second detector module and a first slot of the printed circuit board by use of the adapter. The adapter makes possible simple and rapid faultfinding of a defective component of the detector by way of a first and a second measurement, in which measurements a position of the faulty output signal is determined.

Abstract: A radiation detector is disclosed for the detection of ionizing radiation, preferably in a medical diagnosis and/or therapy system, having at least one detector element which is at least partially enclosed by an encapsulation compound. The encapsulation compound at least partially reflects light which is produced during the absorption of the ionizing radiation in the at least one detector element. Further, the detection of the radiation is carried out indirectly by detection of the generated light, wherein the encapsulation compound is made of a multicomponent mixture which converts compounds produced because of radiation, which generate color changes of the encapsulation compound, at least partially into colorless nonabsorbing compounds.

Abstract: To permit straightforward assembly of an X-ray detector including matricially arranged detector modules, detector modules are initially combined to form a bar. A plurality of the bars are subsequently fastened next to one another on a detector support mechanism to form the X-ray detector.

Abstract: A method and a control device are for controlling the temperature of a detector system inside a computed tomography unit. The CT unit includes a rotatable gantry with a gantry housing in which both an X-ray tube and the detector system are located. The detector system is arranged, in turn, inside a detector housing. The air temperature is set in the gantry housing via a temperature-controlled air circulation. The temperature of the ambient air of the detector housing is set by a control system that uses the temperature of the detector system as controlled variable.