A wireless transmission system includes a first substrate and a second substrate. A first coil used for wireless power transmission, a first light emitting element that is arranged inside the first coil and that is used for wireless communication, and a first light receiving element arranged on the same circumference as that of the first light emitting element are arranged on the first substrate. The first substrate and the second substrate are arranged so as to be opposed to each other so that a second light emitting element and a second light receiving element, which are arranged on the second substrate, are opposed to the first light emitting element and the first light receiving element.

The present inventive concept relates to a thermal radiation body for cooling a heating element, which includes a pattern unit including a pore part provided as an empty space or filled with a gas phase and a cover part covering the pore part and dissipates heat of the heating element through heat radiation.

The present inventive concept relates to a thermal radiation body for cooling a heating element, which includes a pattern unit including a pore part provided as an empty space or filled with a gas phase and a cover part covering the pore part and dissipates heat of the heating element through heat radiation.

A display may include a color filter layer, a liquid crystal layer, and a thin-film transistor layer. A camera window may be formed in the display to accommodate a camera. The camera window may be formed by creating a notch in the thin-film transistor layer that extends inwardly from the edge of the thin-film transistor layer. The notch may be formed by scribing the thin-film transistor layer around the notch location and breaking away a portion of the thin-film transistor layer. A camera window may also be formed by grinding a hole in the display. The hole may penetrate partway into the thin-film transistor layer, may penetrate through the transistor layer but not into the color filter layer, or may pass through the thin-film transistor layer and partly into the color filter layer.

A display may include a color filter layer, a liquid crystal layer, and a thin-film transistor layer. A camera window may be formed in the display to accommodate a camera. The camera window may be formed by creating a notch in the thin-film transistor layer that extends inwardly from the edge of the thin-film transistor layer. The notch may be formed by scribing the thin-film transistor layer around the notch location and breaking away a portion of the thin-film transistor layer. A camera window may also be formed by grinding a hole in the display. The hole may penetrate partway into the thin-film transistor layer, may penetrate through the transistor layer but not into the color filter layer, or may pass through the thin-film transistor layer and partly into the color filter layer.

An encapsulation cover for an electronic package includes a frontal wall with a through-passage extending between faces. The frontal wall includes an optical element that allows light to pass through the through-passage. A cover body and a metal insert that is embedded in the cover body, with the cover body being overmolded over the metal insert, defines at least part of the frontal wall.

A transparent display substrate, a transparent display panel and a display device. The display substrate includes at least one pixel unit. The at least one pixel unit includes at least three sub-pixel groups emitting light of different colors. The sub-pixel groups includes at least two sub-pixels, and the sub-pixels include a first electrode, a light-emitting structure block located on the first electrode, and a second electrode located on the light-emitting structure block. In the at least one pixel unit, two first electrodes of two adjacent sub-pixels in a sub-pixel group are electrically connected by a first connecting portion, two first electrodes of two sub-pixels in another of the sub-pixel groups are electrically connected by a second connecting portion. The second connecting portion at least partially surrounds sides of the sub-pixels in other sub-pixel groups. The first connecting portion and the second connecting portion are located in a same layer.

The problem of the present disclosure is to provide a photo sensor circuit that uses oxide semiconductor transistors and the operation of which is stable. The photo sensor circuit includes: a photo transistor; a first switching transistor; a second switching transistor; and a capacitance element. The photo transistor includes: a gate connected to a first wiring; a source connected to a second wiring; and a drain. The first switching transistor includes: a gate connected to a third wiring; a source connected to a fourth wiring; and a drain connected to the drain of the photo transistor. The capacitance element includes: a first terminal connected to the drain of the photo transistor; and a second terminal connected to the source of the first switching transistor. The second switching transistor includes: a gate connected to a gate line; a source connected to a signal line; and a drain connected to the first terminal of the capacitance element. Each of the photo transistor, the first switching transistor, and the second transistor includes an oxide semiconductor layer as a channel layer.

The present disclosure is directed to optoelectronic modules with substantially temperature-independent performance characteristics and host devices into which such optoelectronic modules can be integrated. In some instances, an optoelectronic module can collect proximity data using light-generating components and light-sensitive components that exhibit temperature-dependent performance characteristics. The light-generating components and light-sensitive components can be configured such that they exhibit complementing temperature-dependent performance characteristics such that the operating performance of the optoelectronic module is substantially temperature independent.

The present disclosure is directed to optoelectronic modules with substantially temperature-independent performance characteristics and host devices into which such optoelectronic modules can be integrated. In some instances, an optoelectronic module can collect proximity data using light-generating components and light-sensitive components that exhibit temperature-dependent performance characteristics. The light-generating components and light-sensitive components can be configured such that they exhibit complementing temperature-dependent performance characteristics such that the operating performance of the optoelectronic module is substantially temperature independent.