Abstract: The present embodiments relate to a radiation generation unit for a therapy system. The radiation generation unit has a radiation source and support components for the radiation source. The radiation generation unit includes a power source and has a mechanical interface, with which the radiation generation unit may be attached to a stand. Degrees of freedom of movement may easily be implemented using a corresponding movement of the radiation generation unit.

Abstract: Reliable electrical contact is made with electronic components and effective electrical isolation is produced between the top and bottom of the electronic components. An electronic component is arranged inside a window in a first layer on a substrate. Next, a second layer is put on such that contact areas on the component and contact points on the first layer are freely accessible. Electrical contacts and electrical connecting lines are produced by electrodeposition. The second layer is used to produce bridges over an interval range between the electronic component and the first layer. The bridges have connecting lines formed on them. The second layer can be removed again. Radio-frequency modules can be produced in compact fashion and can be combined with audio-frequency components.

Abstract: One unhoused electronic component, e.g., a semiconductor power component, has at least one connecting surface disposed on a top side and/or on a bottom side for fastening and/or for electric contacting. One side of the component is attached to and/or electrically contacts a direct copper bonding ceramic substrate, at an opposing connecting surface in the region of the connecting surface. An electrically insulating carrier film is created on the substrate on the side facing the component outside the region of the connecting surface and extending beyond the bottom side. An electrically conducting conductor part is attached to and/or electrically contacts the connecting surface on the top side. A pre-formed, three dimensional structure is formed extending beyond the area of the top side, thus creating an electrically insulating mass between the carrier film and the three-dimensional structure of the conductor part.

Abstract: The present embodiments relate to a radiation generation unit for a therapy system. The radiation generation unit has a radiation source and support components for the radiation source. The radiation generation unit includes a power source and has a mechanical interface, with which the radiation generation unit may be attached to a stand. Degrees of freedom of movement may easily be implemented using a corresponding movement of the radiation generation unit.

Abstract: One unhoused electronic component, e.g., a semiconductor power component, has at least one connecting surface disposed on a top side and/or on a bottom side for fastening and/or for electric contacting. One side of the component is attached to and/or electrically contacts a direct copper bonding ceramic substrate, at an opposing connecting surface in the region of the connecting surface. An electrically insulating carrier film is created on the substrate on the side facing the component outside the region of the connecting surface and extending beyond the bottom side. An electrically conducting conductor part is attached to and/or electrically contacts the connecting surface on the top side. A pre-formed, three dimensional structure is formed extending beyond the area of the top side, thus creating an electrically insulating mass between the carrier film and the three-dimensional structure of the conductor part.

Abstract: Reliable electrical contact is made with electronic components and effective electrical isolation is produced between the top and bottom of the electronic components. An electronic component is arranged inside a window in a first layer on a substrate. Next, a second layer is put on such that contact areas on the component and contact points on the first layer are freely accessible. Electrical contacts and electrical connecting lines are produced by electrodeposition. The second layer is used to produce bridges over an interval range between the electronic component and the first layer. The bridges have connecting lines formed on them. The second layer can be removed again. Radio-frequency modules can be produces in compact fashion and can be combined with audio-frequency components.

Abstract: A component is connected to a circuit carrier via contacts which place the component at a distance from the circuit carrier. A foil is applied to the component and the circuit carrier so that it lies close to the surface of the circuit carrier on which the component is located and to the sides of the component not facing the circuit carrier. After being applied to the component and the circuit carrier the film is provided with a metal coating.

Abstract: The product comprises a sensor (1) via which a measured quantity that corresponds to reactive resistance can be furnished within a measuring range. The product also comprises a matching network (2) and a surface wave element (3). The sensor (1) is connected to a first reflector (4) of the surface wave element (3) via the matching network (2). The first reflector (4) forms, together with the matching network (2) and the sensor (1), a resonator which, for a value of the measured quantity within the measuring range, has a resonance with regard to a reflection of an acoustic surface wave on the first reflector (4). The invention also relates to a method for determining the measured quantity and to a corresponding system.

Abstract: The product comprises a sensor (1) via which a measured quantity that corresponds to a reactive resistance can be furnished within a measuring range. The product also comprises a matching network (2) and a surface wave element (3). The sensor (1) is connected to a first reflector (4) of the surface wave element (3) via the matching network (2). The first reflector (4) forms, together with the matching network (2) and the sensor (1), a resonator which, for a value of the measured quantity within the measuring range, has a resonance with regard to a reflection of an acoustic surface wave on the first reflector (4). The invention also relates to a method for determining the measured quantity and to a corresponding system.

Abstract: An electrical-technical product has a sensor (1) through which can be supplied a measured variable corresponding to a reactive resistance within a range of measurement, a matching network (2) and a surface acoustic wave (SAW) element in which the sensor is connected via the matching network (2) to a first reflector of the SAW element (3), and the first reflector (4) forms a resonator with the matching network (2) and the sensor (1). The resonator for one value of the measured variable within the range of measurement, is tuned to an acoustic surface wave on the surface wave element (3), in view of a reflection of the surface wave propagating at the first reflector (4). The resonance is determined by a maximum reflectivity of the first reflector (4).