Abstract: Methods for manufacturing an ultra-thin display assembly with integrated touch functionality may include edge bonding a laminate layer to a backlight portion of an LCD module. A display portion of the LCD module may be direct bonded to a cover glass including a transparent conductive electrode layer. The cover glass may be manufactured from a large glass sheet and may have an edge polymer deposited on edges of the cover glass, a conductive polymer layer over the transparent conductive electrode layer, and a smart polymer at the edges of the cover glass.

Abstract: Methods for manufacturing an ultra-thin display assembly with integrated touch functionality may include edge bonding a laminate layer to a backlight portion of an LCD module. A display portion of the LCD module may be direct bonded to a cover glass including a transparent conductive electrode layer. The cover glass may be manufactured from a large glass sheet and may have an edge polymer deposited on edges of the cover glass, a conductive polymer layer over the transparent conductive electrode layer, and a smart polymer at the edges of the cover glass.

Abstract: Methods for manufacturing a metal foam and a metal foam reinforced back plate may be used to provide high-strength and low weight structural elements in portable information handling systems. A method for manufacturing a metal foam may include selectively adding iridium oxide and ceramic particulate to a light-metal allow to create desired mechanical properties of the metal foam.

Abstract: Methods for manufacturing a metal foam and a metal foam reinforced back plate may be used to provide high-strength and low weight structural elements in portable information handling systems. A method for manufacturing a metal foam may include selectively adding iridium oxide and ceramic particulate to a light-metal allow to create desired mechanical properties of the metal foam.

Abstract: Methods for manufacturing a metal foam and a metal foam reinforced back plate may be used to provide high-strength and low weight structural elements in portable information handling systems. A method for manufacturing a metal foam may include selectively adding iridium oxide and ceramic particulate to a light-metal allow to create desired mechanical properties of the metal foam.

Abstract: Color mixing using the reflective properties of an OLED is provided. At least one OLED is used to reflect light from at least one other light source such that light from the OLED and the additional light source are combined. Light from the additional light source is reflected from a surface in the OLED provided by e.g., the cathode of the OLED. By carefully selecting the individual light colors of the OLED and the additional light source, their combined light can provide a light color different from either the OLED or the additional light source alone.

Abstract: Methods for manufacturing a metal foam and a metal foam reinforced back plate may be used to provide high-strength and low weight structural elements in portable information handling systems. A method for manufacturing a metal foam may include selectively adding iridium oxide and ceramic particulate to a light-metal allow to create desired mechanical properties of the metal foam.

Abstract: Methods for manufacturing an ultra-thin display assembly with integrated touch functionality may include edge bonding a laminate layer to a backlight portion of an LCD module. A display portion of the LCD module may be direct bonded to a cover glass including a transparent conductive electrode layer. The cover glass may be manufactured from a large glass sheet and may have an edge polymer deposited on edges of the cover glass, a conductive polymer layer over the transparent conductive electrode layer, and a smart polymer at the edges of the cover glass.

Abstract: An apparatus and method of detecting ambient light in a lighting system is provided. An OLED may be used to emit light and detect ambient light in such a system. Detection can occur during a time interval when light is not emitted from the OLED. Feedback to control the emitted light level of the OLED can be based on the detected ambient light.

Abstract: A daylight sensor system includes a power circuit that converts high voltage AC to low voltage DC. The system includes a microcontroller, a motion detector, and a photodiode (PD) integrated circuit (IC). The PD IC provides an output to the microcontroller that is indicative of a lux reading in the vicinity of the system. In response, the microcontroller activates or deactivates a latching relay, which is connected to a line voltage and a load. The motion detector whether the daylight sensor system will be in an active mode of operation or an inactive mode. The microcontroller is programmed so that if the motion detector fails to detect motion for a certain amount of time, the microcontroller will go off line until the motion detector senses motion again.

Abstract: An apparatus and method of detecting ambient light in a lighting system is provided. An OLED may be used to emit light and detect ambient light in such a system. Detection can occur during a time interval when light is not emitted from the OLED. Feedback to control the emitted light level of the OLED can be based on the detected ambient light.

Abstract: Color mixing using the reflective properties of an OLED is provided. At least one OLED is used to reflect light from at least one other light source such that light from the OLED and the additional light source are combined. Light from the additional light source is reflected from a surface in the OLED provided by e.g., the cathode of the OLED. By carefully selecting the individual light colors of the OLED and the additional light source, their combined light can provide a light color different from either the OLED or the additional light source alone.

Abstract: Described is a method for making a flexible OLED lighting device. The method includes forming a plurality of OLED elements on a flexible planar substrate, each of the OLED elements including a continuous respective anode layer formed over the substrate. One or more organic light emitting materials is formed over the anode layer; a continuous cathode layer having a first thickness is formed over the light emitting materials; and a discontinuous cathode layer having a second thickness is formed over the continuous cathode layer. An encapsulating protective cover may be formed over the cathode layers. Each of the OLED elements defines a bendable, continuous light region on the substrate, wherein the substrate and combination of OLED elements define an OLED device that more effectively dissipates heat and has an active light area that is bendable.

Abstract: A method for making a flexible OLED lighting device includes forming a plurality of OLED elements on a flexible planar substrate, wherein at least one of the OLED elements includes a continuous respective anode layer formed over the substrate, one or more organic light emitting materials formed over the anode layer, a cathode layer formed over the light emitting materials, and an encapsulating protective cover formed over the cathode layer. At least one of the OLED elements defines a continuous light region on the substrate, wherein the substrate and combination of OLED elements define an active light area. The active light area is bendable from a flat planar configuration to a bend configuration having a design bending radius. The thickness of the cathode layer is formed between a minimum thickness value and a maximum thickness value as a function of the size of the active light area and the design bending radius. An OLED in accordance with these aspects is also provided.

Abstract: A method for making a flexible OLED lighting device includes forming a plurality of OLED elements on a flexible planar substrate, wherein at least one of the OLED elements includes a continuous respective anode layer formed over the substrate, one or more organic light emitting materials formed over the anode layer, a cathode layer formed over the light emitting materials, and an encapsulating protective cover formed over the cathode layer. At least one of the OLED elements defines a continuous light region on the substrate, wherein the substrate and combination of OLED elements define an active light area. The active light area is bendable from a flat planar configuration to a bend configuration having a design bending radius. The thickness of the cathode layer is formed between a minimum thickness value and a maximum thickness value as a function of the size of the active light area and the design bending radius. An OLED in accordance with these aspects is also provided.