An electroluminescent assembly on a vehicle A-pillar and a method for installing the same on a vehicle A-pillar includes a panel positioned over an interior surface of the A-pillar, the panel including a plurality of facets extending along a length of the panel. The electroluminescent assembly covers the three facets. The portion of the electroluminescent assembly that covers a middle facet provides real-time visual indicators to an occupant of the vehicle based on signals derived from a vehicle electronic system. The portion of the electroluminescent assembly that covers the other two facets provide illumination to an interior and exterior of the vehicle.

A light emitting device is disclosed, including a first electrode layer, a second electrode layer, and an organic light emitting layer sandwiched between the first and second electrode layers. The second electrode layer is patterned to form a plurality of electrode patterns arranged with different densities. The organic light emitting layer is subjected to a color separation process to form a plurality of monochromatic blocks that correspond to the electrode patterns, respectively. The electrode patterns are divided into a plurality of electrode pattern groups arranged in an alternate manner. The electrode pattern groups display a same image, and a same voltage is applied to the electrode pattern groups at a same time. Alternatively, the electrode pattern groups display different images, and a same or different voltages are applied to the electrode pattern groups at different times. As such, the light emitting device generates grayscale, full-color, three-dimensional or dynamic images.

A transparent display apparatus is provided that is constructed to transmit or block a light of images selectively according to a supply of electric power to a conventional transparent organic light emitting diode. The transparent display apparatus includes a transparent organic light emitting diode having a glass substrate, a transparent anode, a hole transport layer, an emitting layer, an electron transport layer and a transparent cathode. The transparent display apparatus includes an insulating layer stacked on the transparent cathode, and first and second transparent ITOs stacked on the insulating layer to deliver electromotive force onto an entire surface and to transmit or block the light of images according to the on/off state of a power source. The transparent display apparatus also includes an electro chromic layer provided between the first and the second transparent ITOs and including transparent and colorless chemicals. The electro chromic layer forms a color through oxidation-reduction reaction of the chemicals according to the on/off state of the power source to absorb or block the light of images. The transparent display apparatus further includes a substrate stacked on the second transparent ITO.

Packaging label (1) comprising a substrate (10), a display (6) placed above the substrate (10), a control module (4) placed in electrical contact with the display (6) and adapted to control the operation of said display (6), at least one photovoltaic module (2) placed above the substrate (10) and next to the display (6) and predisposed to supply the display (6) and the control module (4); wherein the photovoltaic module (2), the control module (4) and the display (6) are printed on the substrate (10) using a printing ink mixed with dopants.

A light shielding layer (200) is located between a plurality of light-emitting regions (101) when seen in a direction perpendicular to a substrate (100). The light shielding layer (200) includes a light reflection layer (202) and a light absorbing layer (204). The light absorbing layer (204) is located closer to the substrate (100) side in a thickness direction than the light reflection layer (202), and has a light reflectance lower than that of the light reflection layer (202). Further, when seen in the direction perpendicular to the substrate (100), an end of the light reflection layer (202) is located further inside of the light shielding layer (200) than an end of the light absorbing layer (204).

The invention describes an OLED device (1) comprising an organic layer (3) which emits light (L.sub.1) in operation and which is positioned between an essentially transparent anode layer (5) and an essentially opaque cathode layer (7). The cathode layer (7) is deliberately structured along a main extension plane (EP) of the OLED device to comprise at least one cathode region (11, 11a, 11b) in which the cathode layer (7) is 10 present and a plurality of cathode-free regions (13, 13a, 13b) and/or at least one cathode-free region (13, 13a, 13b) of a larger extension, through which cathode-free regions and/or region (13, 13a, 13b) visible light (L.sub.2) can pass in the direction of a cross extension (CE) of the OLED device. The invention also describes a production method of such OLED device (1).

A profiled display panel, including a display area. The display area includes a plurality of display sub-areas; a plurality of cascade signal lines for coupling adjacent two of the gate driving sub-circuits. At least one cascade signal line includes a first cascade trace extending in a first direction and a second cascade trace extending in a second direction. The first cascade trace includes a plurality of first conductive patterns arranged on a first conductive layer and second conductive pattern arranged on a second conductive layer. The plurality of first conductive patterns are electrically connected to the second conductive pattern; and the second cascade trace includes a third conductive pattern arranged on the first conductive layer.

An organic EL element 1 according to one embodiment of the present invention is an organic EL element comprising: a continuous first electrode 20; a continuous second electrode 70; and a light emitting layer 50 arranged between the first electrode 20 and the second electrode 70, wherein the light emitting layer 50 has two light emitting regions 51, 52 and wherein the two light emitting regions 51, 52 are different in at least one of emission color and emission luminance.

According to the present disclosure, an optoelectronic component is provided with an organic layer stack, in which light is generated in operation of the optoelectronic component, at least one marking element, by means of which the optoelectronic component is identifiable, wherein the at least one marking element can be read out under irradiation using electromagnetic radiation from the nonvisible spectral range, the at least one marking element can be read out at a main surface of the optoelectronic component, and wherein the at least one marking element is arranged at or under the main surface in the region of the illuminated area.

A luminous means comprising a substrate having a first main surface, to which a first electrode is applied, a second electrode, an organic layer stack within an active region of the substrate between the first and the second electrode, wherein the organic layer stack comprises at least one organic layer which is suitable for generating light, and at least one reflective element, which is formed along a main plane of the luminous means, wherein the luminous means has two operating states, such that the luminous means is an illumination source in a first operating state and the luminous means is a mirror in a second operating state.