Abstract: For the production of a white LED having a predetermined color temperature, a blue LED (2a-2d) or a UV LED is coated with a conversion layer (5) which absorbs the blue light or UV light and emits light of greater wavelength. In accordance with the invention, the exact wavelength of the LED (2a-2d) is determined and the color conversion agent (5) is applied over this LED (2a-2d) in a quantity dependent upon the determined wavelength. Through this, the tolerance of the color temperature can be significantly reduced. The color conversion agent may be applied by means of dispenser or stamp, and the quantity and/or concentration selected in dependence upon the determined wavelength. Inkjet printing, deposition from the gas phase or selective removal by means of a laser is, however, also possible. The invention also relates to light sources produced in accordance with this method.

Abstract: An LED die (3) is arranged with an adhesive (4) on an LED PCB (6). The LED PCB (6) has on the side opposite to the LED die (3) rear side contacts (7). Through this a self-contained LED lamp is formed, which e.g. can be applied by means of SMT to a board (9) or introduced into a lamp socket. In accordance with the invention, the rear side contacts (7) cover at least the half area, preferably the entire area apart from necessary exceptions, of the LED PCB (6). Through this, the heat can be discharged with slight thermal resistance. Preferably a cooling body (11) is arranged on the rear side of the board (9). In this case it is expedient if the board (9) has through-contacts for increasing the thermal conductivity.

Abstract: For the production of a white LED having a predetermined color temperature, a blue LED (2a-2d) or a UV LED is coated with a conversion layer (5) which absorbs the blue light or UV light and emits light of greater wavelength. In accordance with the invention, the exact wavelength of the LED (2a-2d) is determined and the color conversion agent (5) is applied over this LED (2a-2d) in a quantity dependent upon the determined wavelength. Through this, the tolerance of the color temperature can be significantly reduced. The color conversion agent may be applied by means of dispenser or stamp, and the quantity and/or concentration selected in dependence upon the determined wavelength. Inkjet printing, deposition from the gas phase or selective removal by means of a laser is, however, also possible. The invention also relates to light sources produced in accordance with this method.

Abstract: For the production of a white LED having a predetermined color temperature, a blue LED (2a-2d) or a UV LED is coated with a conversion layer (5) which absorbs the blue light or UV light and emits light of greater wavelength. In accordance with the invention, the exact wavelength of the LED (2a-2d) is determined and the color conversion agent (5) is applied over this LED (2a-2d) in a quantity dependent upon the determined wavelength. Through this, the tolerance of the color temperature can be significantly reduced. The color conversion agent may be applied by means of dispenser or stamp, and the quantity and/or concentration selected in dependence upon the determined wavelength. Inkjet printing, deposition from the gas phase or selective removal by means of a laser is, however, also possible. The invention also relates to light sources produced in accordance with this method.

Abstract: A thin-film assembly (1) including a substrate (2) and at least one electronic thin-film component (8) applied on the substrate by thin-film technology, wherein a base electrode (4) is provided on the substrate, on which base electrode thin-film layers (21) forming part of the thin-film component are arranged together with an upper top electrode (9); the substrate (2) is comprised of a printed circuit board (2) known per se and including an insulation-material base body (3) and a metal coating as the conductor layer (5), wherein the conductor layer (5) forms the base electrode (4) and, to this end, is smoothed at least on the location of the thin-film component (8), and wherein a contact layer (18) is applied by thin-film technology between the smoothed, optionally reinforced, conductor layer (5) and the superimposed thin-film layers (21) of the thin-film component (8), which contact layer is physically or chemically adsorbed on the surface of the base electrode (4).

Abstract: Disclosed is a printed circuit board element comprising an optical waveguide and an embedded optoelectronic element.

Abstract: The invention relates to a PCB blank comprising a protective film which is resistant to acid and which is made of at least two layers which are chemically linked to each other underneath each other and/or are linked to the metal surface of the PCB blank. The invention also relates to a method for coating a PCB blank with a protective film which is resistant to acid and which is made of at least two layers.

Abstract: An LED die (3) is arranged with an adhesive (4) on an LED PCB (6). The LED PCB (6) has on the side opposite to the LED die (3) rear side contacts (7). Through this a self-contained LED lamp is formed, which e.g. can be applied by means of SMT to a board (9) or introduced into a lamp socket. In accordance with the invention, the rear side contacts (7) cover at least the half area, preferably the entire area apart from necessary exceptions, of the LED PCB (6). Through this, the heat can be discharged with slight thermal resistance. Preferably a cooling body (11) is arranged on the rear side of the board (9). In this case it is expedient if the board (9) has through-contacts for increasing the thermal conductivity.

Abstract: For the production of a white LED having a predetermined color temperature, a blue LED (2a-2d) or a UV LED is coated with a conversion layer (5) which absorbs the blue light or UV light and emits light of greater wavelength. In accordance with the invention, the exact wavelength of the LED (2a-2d) is determined and the color conversion agent (5) is applied over this LED (2a-2d) in a quantity dependent upon the determined wavelength. Through this, the tolerance of the color temperature can be significantly reduced. The color conversion agent may be applied by means of dispenser or stamp, and the quantity and/or concentration selected in dependence upon the determined wavelength. Inkjet printing, deposition from the gas phase or selective removal by means of a laser is, however, also possible. The invention also relates to light sources produced in accordance with this method.

Abstract: An electroluminescence color display screen comprising an organic electroluminescence layer disposed between a patterned base electrode layer and a patterned top electrode layer, and further comprising a color conversion layer and a spectrally selective reflector for improving the color efficiency of the color display screen.

Abstract: Electroluminescence color display screen with matrix picture elements (pixels), the display screen comprising a system of single layers applied on top of and partially next to one another, the layer system comprising an insulating, optically at least translucent base layer, a conductive, optically at least translucent base electrode, a patterned electrically insulating intermediate layer, if necessary, one or several color conversion layers applied in form of a matrix and, if necessary, one or several index matching layers, wherein the base electrode is deposited as a continuous layer upon the entire area of the base layer, wherein the insulating intermediate layer encloses and projects past pixel areas made of the organic electroluminescence layer and arranged to form a matrix, and wherein the top electrode applied on top of each pixel area extends partially across the adjacent lattice wall.

Abstract: Use in electrooptical switching and display devices of a polymer comprising conjugatively linked chromophore segments whose emission properties are determined by the emission properties of the individual chromophore segments.Electroluminescence devices comprising the polymers of the present invention have, inter alia, a high color purity. The polymers used according to the present invention enable, in particular, blue and white electroluminescence to also be achieved.