A virtual reality (VR) headset, system, and method of fabrication are disclosed. The VR headset includes a frame, a transparent display that includes an array of light-emitting diodes (LEDs), and a darkening layer having a controllable opacity, and a processor controlling the display and darkening layer. A proximity sensor detects a potential collision, and the opacity is changed from opaque to transparent in response to detection of the potential collision. The opacity is changed in response to activation of a virtual user input or predetermined eye movement.

An interposer may include a temporary substrate, a common pad disposed on the temporary substrate and light emitting diodes (LEDs) disposed on the common pad. Each of the light emitting diodes may include a first electrode, a first semiconductor layer, an emission layer, a second semiconductor layer, a second electrode, and a passivation layer. The second electrode, the second semiconductor layer, the emission layer, the first semiconductor layer and the first electrode may have a structure formed from sequential lamination. The passivation layer may enclose the second semiconductor layer, the emission layer and the first semiconductor layer. The common pad may be electrically connected to the second electrode at a lower side of the light emitting diodes. The first electrode in each of the light emitting diodes may extend to an upper portion of the passivation layer. A method for inspecting light emitting diodes disposed on a temporary substrate is also disclosed.

A printed circuit board (PCB) assembly may include a PCB comprising a base layer, an electrical layout layer, and a dielectric located between the base layer and the electrical layout layer. The electrical layout layer may include a plurality of electrical pads and a plurality of electrical traces. The PCB assembly may include an emitter assembly comprising a plurality of emitters configured to emit light. The plurality of emitters may be mounted to the PCB and electrically connected to the electrical pads via respective wind bonds. The PCB assembly may include drive circuitry configured to control power delivered to the plurality of emitters. The drive circuitry may be mounted to the PCB and electrically connected to the electrical pads via respective solder connections. The PCB assembly may include communication circuitry configured to cause the drive circuitry to control the emitters in response to messages received via wireless signals.

A display module includes: a substrate including a mounting surface on which a plurality of inorganic light-emitting diodes emitting light in a first direction are mounted, a side surface, and a rear surface being opposite to the mounting surface; a front cover bonded with the mounting surface and covering the mounting surface in the first direction; a metal plate bonded with the rear surface; a side cover surrounding the side surface; and a side end member covering at least one portion of the side cover and extending in a second direction being orthogonal to the first direction along the side surface, wherein the side end member includes a body extending in the second direction, and a plurality of ribs extending from the body in the first direction and arranged at intervals along the second direction.

A light-emitting device includes an insulating substrate having one or more first cutouts and one or more second cutouts provided on opposite side surfaces thereof. First and second wiring electrodes, which are separated from each other, correspond respectively to the first and second cutouts. The first and second wiring electrodes each cover a region that extends over an edge of the corresponding cutout on an upper surface of the substrate and a region that extends over an edge the corresponding cutout on a lower surface of the substrate from an internal surface of the cutout. First and second resin films cover surfaces the first and second wiring electrodes in regions that extend over edges along the first and second cutouts in a top view. A light-emitting element is placed on the substrate to allow power to be supplied by the first wiring electrode and the second wiring electrode.

A manufacturing method of a display device includes providing a plurality of pad electrodes exposed through an opening defined through a base layer and arranged in a first direction and a plurality of bump electrodes on the pad electrodes overlapping the pad electrodes, respectively, when viewed in a plane, placing a preliminary metal layer having a substantially non-uniform thickness in a second direction intersecting the first direction on the pad electrodes and the bump electrodes, placing a mold on the preliminary metal layer to form a metal layer with a flat upper surface, and irradiating a laser to a first portion of the metal layer, the first portion of the metal layer not overlapping the pad electrodes and the bump electrodes, to form a plurality of metal patterns. The pad electrodes are electrically connected to the bump electrodes by (via) the metal patterns.

A light-emitting component includes a connection board with a mounting side. The light-emitting component also includes a light source. The light source is fastened and electrically connected to the connection board on the mounting side. The light-emitting component further includes a cover which covers the connection board in places on its mounting side and laterally surrounds the light source. The light-emitting component additionally includes an optical element. The optical element has a central region which is arranged downstream of the light source on the mounting side of the connection board. A provision is made to prevent impingement of light in the central region of the optical element.

A display module includes: a substrate including a mounting surface on which a plurality of inorganic light-emitting diodes emitting light in a first direction are mounted, a side surface, and a rear surface being opposite to the mounting surface; a front cover bonded with the mounting surface and covering the mounting surface in the first direction; a metal plate bonded with the rear surface; a side cover surrounding the side surface; and a side end member covering at least one portion of the side cover and extending in a second direction being orthogonal to the first direction along the side surface, wherein the side end member includes a body extending in the second direction, and a plurality of ribs extending from the body in the first direction and arranged at intervals along the second direction.

The present application provides a light-emitting diode, a light-emitting substrate, and a display device. The light-emitting diode includes a first semiconductor layer, a light-emitting layer, a second semiconductor layer, and a first protective layer arranged in sequence. A surface of the second semiconductor layer away from the light-emitting layer is a first diffusion surface, the first diffusion surface includes a first central curved surface and a first edge curved surface connected to the first central curved surface, the first central curved surface is concave towards the light-emitting layer, and the first edge curved surface is convex towards the light-emitting layer.

This application relates to a light-emitting device and a manufacturing method thereof, comprising a substrate, a plurality of light-emitting chips arranged on the front side of the substrate, and an encapsulation layer disposed on the substrate to cover each light-emitting chip. The encapsulation layer allows light emitted by the LED chips to pass through.