Disclosed is a display apparatus having a substrate including a display area and a non-display area adjacent to the display area. Here, the substrate may be variable, pliable, rollable, flexible, foldable, stretchable, bendable, wearable, or the like. The display apparatus includes a plurality of connection wirings disposed on the substrate. The display apparatus includes a cover window disposed at least over the plurality of connection wirings. The display apparatus includes a light-blocking pattern part included in the cover window.

A quantum technological, micro-optical, micro-electronic or photonic system, includes a planar substrate, a microelectronic circuit which is part of the substrate; at least one electrical component comprised within the microelectronic circuit, a micro-optical subdevice which is part of the planar substrate, one or more nanoparticles being diamonds; and a colloidal film, wherein the one or more nanoparticles are comprised within the first portion of the colloidal film. The colloidal film includes the one or more nanoparticles. The system further comprises at least one light-emitting electro-optical component. The light-emitting electro-optical component interacts with the electrical component via the micro-optical subdevice. The one or more nanoparticles include two NV centers. The at least two NV centers interact with one another in a physically observable manner. The interaction between the light-emitting component and the electrical component takes place with involvement of the at least two NV centers.

A quantum technological, micro-optical, micro-electronic or photonic system, includes a planar substrate, a microelectronic circuit which is part of the substrate; at least one electrical component comprised within the microelectronic circuit, a micro-optical subdevice which is part of the planar substrate, one or more nanoparticles being diamonds; and a colloidal film, wherein the one or more nanoparticles are comprised within the first portion of the colloidal film. The colloidal film includes the one or more nanoparticles. The system further comprises at least one light-emitting electro-optical component. The light-emitting electro-optical component interacts with the electrical component via the micro-optical subdevice. The one or more nanoparticles include two NV centers. The at least two NV centers interact with one another in a physically observable manner. The interaction between the light-emitting component and the electrical component takes place with involvement of the at least two NV centers.

A lens comprises a first surface and a second surface opposite the first surface. The first surface includes a first convex central refractive portion and a total internal reflection (TIR) portion peripheral to the first convex central portion. The second surface includes a second convex central refractive portion and a peripheral refractive portion having a curvature different from a curvature of the second convex central refractive portion. The first convex central refractive portion and the second convex central refractive portion are shaped to collimate or partially collimate light via refraction at the first convex central portion followed by refraction at the second convex central portion. The TIR portion and the peripheral refractive portion are shaped to collimate or partially collimate light by total internal reflection at the TIR portion followed by refraction at the peripheral refractive portion.

A meta-optics display device for use with an information handling system. The meta-optics display device includes a plurality of micro-LED pillars, and, a plurality of micro-sensors, at least some of the plurality of micro-sensors being associated with respective micro-LED pillars of the plurality of micro-LED pillars, the plurality of micro-sensors comprising a first set of micro-sensors and a second set of micro-sensors, the first set of micro-sensors being tuned for a first focal distance, the second set of micro-sensors being tuned for a second focal distance.

A display device including a display module and a backlight module is provided. The display module has a display region. The backlight module is overlapped with the display module and includes a plurality of light emitting diodes. The plurality of light emitting diodes form a light emitting region. The light emitting region is overlapped with the display region, and an area of the light emitting region is larger than an area of the display region.

The present disclosure provides a light emitting diode structure. The light emitting diode structure includes a substrate, a first light emitting structure on the substrate, a second light emitting structure on the substrate, and a third light emitting structure on the substrate. The first light emitting structure includes a first light emitting diode and a first focusing optic on the first light emitting diode. The second light emitting structure includes a second light emitting diode and a second focusing optic on the second light emitting diode. The third light emitting structure includes a third light emitting diode and a third focusing optic on the third light emitting diode. The first light emitting structure, the second light emitting structure and the third light emitting structure are arranged along a first direction and are dislocated in a second direction perpendicular to the first direction.

A display apparatus may include a substrate; a plurality of pixels on the substrate in a row direction and a column direction and including a plurality of sub-pixels; a plurality of sub-pixel circuits in the plurality sub-pixels on the substrate; and a plurality of gate lines on the substrate and connected to the plurality of sub-pixel circuits. Each of the plurality of sub-pixels may include a plurality of sub-light emitting diodes configured to emit light of the same color, at least one sub-light emitting diode of one sub-pixel included in one of the plurality of pixels may be configured to be driven by a gate line, and a sub-light emitting diode of another sub-pixel included in the same one of the plurality of pixels may be configured to be driven by another gate line that is different from the gate line.

In an embodiment a method for producing an optoelectronic assembly includes providing at least one component of the optoelectronic assembly, providing a source carrier with a functional material on a lower face of the source carrier facing the at least one component, detaching a part of the functional material by irradiation via a laser beam through an upper face of the source carrier facing away from the at least one component, attaching the detached part of the functional material to a side of the at least one component facing the source carrier and completing the optoelectronic assembly, wherein the source carrier comprises cavities, each cavity being filled with the functional material.

There is provided a light emitting device (10) including a plurality of pixels (20) arranged on a substrate, in which a pixel of the plurality of pixels includes a plurality of subpixels (100), at least one subpixel of the plurality of subpixels includes a plurality of light emitting elements (200), each light emitting element includes: a first electrode (202) provided on the substrate (300); a light emitting layer (204) that is laminated on the first electrode and emits light; a second electrode (206) that is laminated on the light emitting layer and transmits light from the light emitting layer; and a first protective film (208) that is laminated on the second electrode and transmits light from the light emitting layer, and a second protective film (210) constituting an interface for guiding the light immediately above the light emitting element is embedded between the light emitting elements adjacent.