The present disclosure provides an auxiliary handle device configured to be used in entering or exiting a vehicle. The auxiliary handle device includes a cover unit including first and second movement guides, which define a movement path, a guide frame unit, which is connected to the cover unit so as to be slidably moved along a rail of a mounting plate mounted on a roof of the vehicle, and a handle unit, which is mounted on the cover unit so as to be selectively projected downwards from the mounting plate, the handle unit including a first guide pin and a second guide pin, which are respectively mounted in the first movement guide and the second movement guide such that the first and second guide pins are moved while being rotated so as to project the handle unit downwards from the mounting plate.

Provided is a surface light emitting illumination device including: a light guide panel on which a fine pattern is formed; a channel formed in a closed curve shape inside an edge of the light guide panel; an LED strip inserted in the channel, in which a plurality of LED chips are mounted on a flexible substrate at regular intervals; a fixing band inserted in the channel to fix the LED strip so that the LED strip is not separated from the channel; a channel communication part formed in the light guide panel to communicate with the channel.

Systems, methods, and computer-readable media are disclosed for dual-color frontlit displays with near uniform color mixing. In one embodiment, an example device may include a light emitting diode (LED) array that includes a first LED that emits light having a first color and a second LED that emits light having a second color, and a light guide that includes a surface having a first portion adjacent to the first LED and a second portion adjacent to the second LED. The first portion may include a first number of binary element surface features formed on the surface, and the second portion may include a second number of binary element surface features formed on the surface. The first number of binary element surface features may be substantially parallel to a first direction of light emitted from the first LED, and the second number of binary element surface features may be substantially parallel to a second direction of light emitted from the second LED, wherein the second direction is substantially perpendicular to the first direction.

A method of manufacturing a light emitting device includes: a resin layer disposition step including disposing, on a support, a resin layer in an A-stage state; a light emitting element mounting step including mounting a light emitting element on the resin layer such that a first surface faces an upper surface of the resin layer; a load application step including applying a load to the light emitting element so as to embed the semiconductor stack structure at least partly in the resin layer while a second surface of the light emitting element is exposed from the resin layer; a first heating step including heating the resin layer at a first temperature without applying the load, to lower a viscosity of the resin layer; and a second heating step including heating the resin layer at a second temperature higher than the first temperature to harden the resin layer.

An optical substrate and a display device are provided. The optical substrate includes a light guide plate and a plurality of light selection units, wherein, the light guide plate includes a light-incident surface and a light-exiting surface, and the light-exiting surface includes a plurality of light-exiting regions; each light selection unit is configured to select light incident from the light-incident surface and propagating in the light guide plate, such that monochromatic light of different colors are emitted from multiple light-exiting regions corresponding to the each light selection unit, and each of the multiple light-exiting regions emits monochromatic light of a single color.

The light emitting device includes a light emitting element having an electrode-formed surface on which electrode posts are formed; a covering member covering the electrode-formed surface and lateral surfaces of the light emitting element while forming an exposure portion of each of the electrode posts which are exposed from the covering member; a pair of electrode layers provided on a surface of the covering member and electrically connected to the exposed portions of the electrode posts; and a pair of electrode terminals which are respectively electrically connected to the electrode layers, having a surface area larger than a surface area of the electrode posts, and having an outer edge positioned at an end portion of the covering member; and an insulating member provided between the pair of the electrode terminals while being in contact with lateral surfaces of the pair of electrode terminals.

A steering wheel assembly having a steering wheel base plate, a safety airbag and a cover and a housing, wherein the cover and the housing define a space for accommodating an airbag and a light-emitting mark. The light-emitting mark includes an electronic control element, a mark portion, and a flexible circuit board. The electronic control element is configured to be based on a rigid printed circuit board. The flexible circuit board is configured to have a first end connected to the electronic control element and a second end connected to the mark portion so that the electronic control element controls light emission of the mark portion by means of the flexible circuit board. The electronic control element is arranged in a first position in the steering wheel assembly. The mark portion is arranged in a second position in the steering wheel assembly. The second position is positioned at the cover.

A mini-LED backlight structure and a backlight module are provided. The mini-LED backlight structure includes a backplate, a glass substrate, and reflective sheets. The glass substrate includes a line surface and a lineless surface close to a side of the backplate. Light emitting diodes and a connector are disposed on the lineless surface. Furthermore, a gap is between the backplate and the glass substrate for disposing the light emitting diodes and the connector. The connector is electrically connected to an external circuit through a conducting wire. Disposing a plurality of elements, the connector, and the light emitting diodes on a same surface of the lineless surface is unlikely affecting backlight effect and saves materials at a same time.

The purpose of the present invention is to realize a lighting device which can be switched between an overall lighting and a local lighting with a single lighting device. The concrete structure is a lighting device including: a first light guide having a first major surface and a first back surface, and a first hole; a second light guide, disposed on the first light guide, and having a second major surface, a second back surface, and a second hole; a reflection sheet disposed under the first back surface of the first light guide; a liquid crystal lens disposed above the second major surface of the second light guide, in which first LEDs and second LEDs are disposed circumferentially along a side wall of the first hole and a side wall of the second hole, respectively, and the first LEDs and the second LEDs are displaced each other in azimuth direction.

An electronic device includes a housing that at least partially defines an exterior surface and an internal volume. The electronic device also includes a display assembly that is at least partially disposed in the internal volume. The display assembly includes a light guide including a transparent plate and a light source positioned at an end of the transparent plate. A light-blocking component is affixed to the housing and at least partially covers a portion of the transparent plate. A translucent portion extends from the light-blocking component and overlaps the transparent plate.