Abstract: The invention relates to an apparatus and a method for evaluating spectral properties of a measurement object. It comprises a plurality of light emission units, each emitting light with a predetermined emission spectrum and having a respective output configured for emitting the light with the predetermined emission spectrum onto the measurement object, an optical spectrograph having an input port adapted to receive light from the measurement object and a diffraction unit adapted to distribute different wavelengths of the received light to different output ports comprising the optical detectors, wherein the diffraction unit is adapted to distribute said received light to the respective output ports such that the lights in the respective output port have different wavelengths at different diffraction orders; a signal identification unit adapted to identify which of the light emission units contribute to the respective light in the respective output ports.

Abstract: The invention relates to an apparatus and a method for evaluating spectral properties of a measurement object. It comprises a plurality of light emission units, each emitting light with a predetermined emission spectrum and having a respective output configured for emitting the light with the predetermined emission spectrum onto the measurement object, an optical spectrograph having an input port adapted to receive light from the measurement object and a diffraction unit adapted to distribute different wavelengths of the received light to different output ports comprising the optical detectors, wherein the diffraction unit is adapted to distribute said received light to the respective output ports such that the lights in the respective output port have different wavelengths at different diffraction orders; a signal identification unit adapted to identify which of the light emission units contribute to the respective light in the respective output ports.

Abstract: In a method and an evaluation device for determining the position of a structure located in an object to be investigated by means of X-ray computer tomography, a cutting data record, which images the object in a cutting plane, is determined from a volume data record of the object. The cutting data record is binarized to form a binary data record, in which the structure voxels imaging the structure and the surface voxels imaging an object surface are determined. To determine the position, a distance data record is produced in such a way that a distance value, which characterizes the smallest distance of the respective distance voxel from the surface voxels, is assigned to each distance voxel of the distance data record. The distance voxels corresponding to the structure voxels are then determined and the associated distance values evaluated.

Abstract: In a method and an evaluation device for determining the position of a structure located in an object to be investigated by means of X-ray computer tomography, a cutting data record, which images the object in a cutting plane, is determined from a volume data record of the object. The cutting data record is binarized to form a binary data record, in which the structure voxels imaging the structure and the surface voxels imaging an object surface are determined. To determine the position, a distance data record is produced in such a way that a distance value, which characterizes the smallest distance of the respective distance voxel from the surface voxels, is assigned to each distance voxel of the distance data record. The distance voxels corresponding to the structure voxels are then determined and the associated distance values evaluated.

Abstract: The invention relates to a method and a device for operating an optical transmitting device having a plurality of optical transmitters that can be driven independently. The method includes detecting the parameter values of the individual transmitters, comparing the parameter values determined with one another and/or with a prescribed comparison value, and selecting one of the transmitters for the communication operation of the transmitting device based on the comparison. The method further includes operating the transmitting device with the selected transmitter.

Abstract: The invention relates to a method and a device for operating an optical transmitting device having a plurality of optical transmitters that can be driven independently. The method includes detecting the parameter values of the individual transmitters, comparing the parameter values determined with one another and/or with a prescribed comparison value, and selecting one of the transmitters for the communication operation of the transmitting device based on the comparison. The method further includes operating the transmitting device with the selected transmitter.

Abstract: The invention relates to an optoelectronic assembly having an optoelectronic or passive optical component and a cooling element for cooling the optoelectronic or passive optical component. According to the invention, the cooling element is a micropeltier cooler, wherein the component is arranged either directly thereon or a carrier substrate is arranged therebetween.

Abstract: A semiconductor component has at least one Peltier element and at least one thermogenerator element that are thermally coupled to one another via a coupling device. By virtue of the thermal coupling of the Peltier element and the thermogenerator element through the coupling device, it is possible to use the Peltier element to cool a microstructure, in particular an optoelectronic component (e.g. a laser diode). Efficient temperature regulation and efficient operation of an optoelectronic component are thus possible.

Abstract: An electrooptical transmitting and/or receiving module has a lead frame and an optoelectronic transducer mounted thereon. The lead frame and the optoelectronic transducer are potted by a shaped body made from transparent, formable material. Introduced into the shaped body is a reflector element. A radiation beam emitted by a transmitter, or a received radiation beam to be directed onto a receiver is deflected at a prescribed angle by the reflector element. The module can be used in an electrooptical transmitting and/or receiving unit which is constructed as a sidelooker. A method is also provided for molding the electrooptical transmitting and/or receiving module.

Abstract: A semiconductor component has at least one Peltier element and at least one thermogenerator element that are thermally coupled to one another via a coupling device. By virtue of the thermal coupling of the Peltier element and the thermogenerator element through the coupling device, it is possible to use the Peltier element to cool a microstructure, in particular an optoelectronic component (e.g. a laser diode). Efficient temperature regulation and efficient operation of an optoelectronic component are thus possible.

Abstract: An optical broadband transmission device for the broadband transmission of data streams between a supply node and a user node. The device comprises an optical fiber for the broadband transmission of data streams between the fiber node and the user node, and a first optical transceiver to the supply node and to the first end of the optical fiber. A second transceiver is connected to the user node and to the second end of the optical fiber. The first and second optical transceiver are designed for transmitting and receiving, respectively, data streams on different optical carrier wavelengths via the optical fiber.

Abstract: A plug-in connecting element is used in optoelectrical devices or subassemblies that have optical components and electrical components, and also in a plug-in connector having two plug-in connecting elements of this type. The plug-in connecting element has in a basic body, at least one electrical interface and at least one optical interface, which can be jointly connected in a pluggable manner to a matching plug-in connecting element. The plug-in connecting element is distinguished by the fact that electrical and optical paths are combined by the integration of an electrical interface and an optical interface in one plug-in connecting element.

Abstract: An electro-optical data transmission module comprises at least a first SMT housing (11) and a second SMT housing (13). A surface-emitting laser light emitter chip is accommodated in the first SMT housing (11), and a light-sensitive light receiver chip is accommodated in the second SMT housing (13). By virtue of the modular design which is formed from at least two individual SMT housings, the electro-optical data transmission module can be implemented with a minimum size.

Abstract: A transmission and reception device, in which the transmission device and the reception device and the input/output end of a glass fiber are disposed optically in series with respect to one another. A laser diode is disposed on a central part of a photosensitive surface and the input/output end of the glass fiber is in turn adjusted in front of its end face. As a result of a cylindrical symmetry of the photosensitive surface and of the laser diode with respect to a fiber axis, a maxima of the coupling curves coincide with the fiber axis, so that a lateral fiber offset leads to only a moderate change in coupling efficiency.

Abstract: A module essentially includes a module housing, into which is introduced a lead frame. An electro-optical transducer is mounted on the lead frame. The interior of the module housing is filled with a transparent potting compound. A plug receptacle part is moulded onto the outer housing wall and has a defined outer contour. Situated in the interior of the plug receptacle part is an optical waveguide piece, which proceeding from the surroundings of an outer area of the plug receptacle part, extends through the interior of the plug receptacle part and through a housing opening right into the housing interior. The optical waveguide piece is optically coupled to the electro-optical transducer. An optical waveguide plug interacting with the module has a sleeve-shaped plug section corresponding to the plug receptacle part.

Abstract: An electrooptical transmitting and/or receiving module has a lead frame and an optoelectronic transducer mounted thereon. The lead frame and the optoelectronic transducer are potted by a shaped body made from transparent, formable material. Introduced into the shaped body is a reflector element. A radiation beam emitted by a transmitter, or a received radiation beam to be directed onto a receiver is deflected at a prescribed angle by the reflector element. The module can be used in an electrooptical transmitting and/or receiving unit which is constructed as a sidelooker. A method is also provided for molding the electrooptical transmitting and/or receiving module.