Abstract: A light deflecting device including a flat, transparent light guide, and a transparent cover layer which is applied to the light guide at least partially in a flat manner. A microstructure for outcoupling light coupled into the light guide is formed between the light guide and the cover layer and the microstructure has a plurality of structural elements which are formed as substantially circular cylindrical elevations. A lighting device and the use of the light deflecting device or lighting device are also disclosed.

Abstract: Disclosed are methods, systems, and articles of manufacture for performing a process on biological samples. An analysis of biological samples in multiple regions of interest in a microfluidic device and a timeline correlated with the analysis may be identified. One or more region-of-interest types for the multiple regions of interest may be determined; and multiple characteristics may be determined for the biological samples based at least in part upon the one or more region-of-interest types. Associated data that respectively correspond to the multiple regions of interest in a user interface for at least a portion of the biological samples in the user interface based at least in part upon the multiple identifiers and the timeline. A count of the biological samples in a region of interest may be determined based at least in part upon a class or type of data using a convolutional neural network (CNN).

Abstract: Disclosed are methods, systems, and articles of manufacture for performing a process on biological samples. An analysis of biological samples in multiple regions of interest in a microfluidic device and a timeline correlated with the analysis may be identified. One or more region-of-interest types for the multiple regions of interest may be determined; and multiple characteristics may be determined for the biological samples based at least in part upon the one or more region-of-interest types. Associated data that respectively correspond to the multiple regions of interest in a user interface for at least a portion of the biological samples in the user interface based at least in part upon the multiple identifiers and the timeline. A count of the biological samples in a region of interest may be determined based at least in part upon a class or type of data using a convolutional neural network (CNN).

Abstract: Disclosed are methods, systems, and articles of manufacture for performing a process on biological samples. An analysis of biological samples in multiple regions of interest in a microfluidic device and a timeline correlated with the analysis may be identified. One or more region-of-interest types for the multiple regions of interest may be determined; and multiple characteristics may be determined for the biological samples based at least in part upon the one or more region-of-interest types. Associated data that respectively correspond to the multiple regions of interest in a user interface for at least a portion of the biological samples in the user interface based at least in part upon the multiple identifiers and the timeline. A count of the biological samples in a region of interest may be determined based at least in part upon a class or type of data using a convolutional neural network (CNN).

Abstract: Disclosed are methods, systems, and articles of manufacture for performing a process on biological samples. An analysis of biological samples in multiple regions of interest in a microfluidic device and a timeline correlated with the analysis may be identified. One or more region-of-interest types for the multiple regions of interest may be determined; and multiple characteristics may be determined for the biological samples based at least in part upon the one or more region-of-interest types. Associated data that respectively correspond to the multiple regions of interest in a user interface for at least a portion of the biological samples in the user interface based at least in part upon the multiple identifiers and the timeline. A count of the biological samples in a region of interest may be determined based at least in part upon a class or type of data using a convolutional neural network (CNN).

Abstract: A light deflecting device including a flat, transparent light guide, and a transparent cover layer which is applied to the light guide at least partially in a flat manner. A microstructure for outcoupling light coupled into the light guide is formed between the light guide and the cover layer and the microstructure has a plurality of structural elements which are formed as substantially circular cylindrical elevations. A lighting device and the use of the light deflecting device or lighting device are also disclosed.

Abstract: The invention relates to the production of an electrooptical printed circuit board (EOLP) and to the use thereof. The optical layer in the printed circuit board is made of highly transparent and soldering bath-resistant polysiloxane wave guides. The polysiloxane wave guides are produced according to casting techniques, and the ends of the wave guides can comprise deviating mirrors which are integrated at 45°. During the casting process of the printed circuit board, the substrate layers and the supersubstrate layers made of polysiloxane are brought into contact with printed circuit board materials having microstructured spacers which are used to define the thickness of the substrate layer and/or the thickness of the supersubstrate layer. Openings are located in the printed circuit board material above the deviating mirrors, such that vertical light decoupling and coupling can take place.

Abstract: The invention relates to the production of an electrooptical printed circuit board (EOLP) and to the use thereof. The optical layer in the printed circuit board is made of highly transparent and soldering bath-resistant polysiloxane wave guides. The polysiloxane wave guides are produced according to casting techniques, and the ends of the wave guides can comprise deviating mirrors which are integrated at 45°. During the casting process of the printed circuit board, the substrate layers and the supersubstrate layers made of polysiloxane are brought into contact with printed circuit board materials having microstructured spacers which are used to define the thickness of the substrate layer and/or the thickness of the supersubstrate layer. Openings are located in the printed circuit board material above the deviating mirrors, such that vertical light decoupling and coupling can take place.

Abstract: The present invention relates to a process for producing a microstructured analytical system including providing at least two plastic components, wetting at least one component, aligning the components, pressing and joining the components together and curing an adhesive.

Abstract: The invention relates to a method for linking two adjacent plastic work pieces (2, 3). The inventive method is characterized in that the intended contact zone (K) of at least one of the two work pieces (2) with which the latter adjoins to the other work piece (3) is at least partially subjected to a high-energy radiation to such an extent that the glass transition temperature is reduced in a marginal zone (R). The two work pieces (2, 3) are brought in the desired position relative to each other. For establishing the connection of the two work pieces (2, 3) at least the marginal zone (R) modified by the previous radiation process is heated at least in its surface area to a temperature that is higher than the glass transition temperature of the marginal zone (R) modified by the radiation process but lower than the glass transition temperature of the zones of the work pieces (2, 3) that have not been modified.

Abstract: According to the invention, waveguides are contained in an optical layer of a printed circuit board. Said waveguides are produced by an embossing process and emit light in a perpendicular manner by means of oblique, reflective ends. Mechanical guide marks are created using the embossing process for positioning couplers, said marks being preferably used as guide holes for MT pins.

Abstract: The invention relates to an optical transceiver module having a circuit board for accommodating electronic components and having at least one optoelectronic transducer. The invention also relates to a method for coupling light into and out of an optical transceiver module. The at least one optoelectronic transducer is configured on one side of the circuit board in such a way that light is coupled in or coupled out essentially perpendicular to the circuit board plane and, in the process, directly from or to the other side of the circuit board.

Abstract: A method of manufacturing passive integrated optical devices from polymeric materials, the method comprising providing a step structure at each transition between a fiber alignment structure and the preform for the light waveguide structure, wherein both of these structures are produced simultaneously. Passive integrated optical devices having ridges or trenches with rectangular cross sections and manufactured to this method are also described.