Provided are a display assembly, a method for manufacturing a display assembly and an electronic device. The display assembly includes: a pixel array including a plurality of pixel units; a photosensitive array including a plurality of photosensitive units, at least one of the photosensitive unit is disposed in a gap between two adjacent pixel units of the pixel array for detecting ambient light through the pixel array.

A metal stem includes a cylindrical portion in which an FPC inserting portion is formed, and a base standing upright from one plane of the cylindrical portion. A tubular lens cap with one open end is fixed to a peripheral portion of the one plane of the cylindrical portion, and has a lens mounted on a bottomed portion. A substrate mounted on one plane of the base includes a signal wiring layer and a ground wiring layer. An optical semiconductor element is mounted on the substrate and has a signal terminal connected to the signal wiring layer of the substrate, and a ground terminal connected to the ground wiring layer of the substrate. An FPC substrate is disposed so as to pass through the FPC inserting portion and to face the one plane of the base. The FPC substrate includes a signal wiring layer connected to the signal wiring layer of the substrate with a metal wire.

A metal stem includes a cylindrical portion in which an FPC inserting portion is formed, and a base standing upright from one plane of the cylindrical portion. A tubular lens cap with one open end is fixed to a peripheral portion of the one plane of the cylindrical portion, and has a lens mounted on a bottomed portion. A substrate mounted on one plane of the base includes a signal wiring layer and a ground wiring layer. An optical semiconductor element is mounted on the substrate and has a signal terminal connected to the signal wiring layer of the substrate, and a ground terminal connected to the ground wiring layer of the substrate. An FPC substrate is disposed so as to pass through the FPC inserting portion and to face the one plane of the base. The FPC substrate includes a signal wiring layer connected to the signal wiring layer of the substrate with a metal wire.

A system and method for robust automatic control of an air-conditioning system in a vehicle includes at least one sensor configured to continuously capture technical driving parameters of the vehicle. The system has a computing unit configured to determine a current air quality from the captured technical driving parameters by way of a suitable algorithm. The system has a control unit configured to control the air-conditioning system in the vehicle, wherein the control of the air-conditioning system includes activating the recirculation circuit of the air-conditioning system and/or activating the fresh-air circuit of the air-conditioning system with reference to the determined air quality.

A positioning device (10) for pivoting at least one relevant component (20) for a motor vehicle headlight about a first and a second axis (X, Y), comprising a holding element (100) for a relevant component (20), said holding element comprising a first sliding surface (110), which is designed as part of a spherical surface, a support frame (200), which comprises a second sliding surface (210), which is designed as part of a spherical surface, the holding element (100) being supported in the support frame (200) by means of a bearing apparatus such that the first sliding surface (110) of the holding element (100) can be displaced along the second sliding surface (210) of the support frame (200) about the first and second axis (X, Y), an adjusting apparatus (300), which has a positioning component (301) and a first moving apparatus (310) and a second moving apparatus (320), which are each arranged on the positioning component (301), which is mechanically connected to the holding element (100) by means of a connecting element (400), wherein the connecting element (400) passes through the support frame (200) via an opening (220), wherein the connecting element (400) is designed to transmit a movement of the positioning component (301) to the holding element (100), and wherein the connecting element is designed as a screw means, wherein the positioning component can be brought into a released state and a fastened state, wherein the positioning component can be displaced when in the released state, and the positioning component (301) can be clamped immovably against the support frame when in the fastened state by tightening the screw means.

A positioning device (10) for pivoting at least one relevant component (20) for a motor vehicle headlight about a first and a second axis (X, Y), comprising a holding element (100) for a relevant component (20), said holding element comprising a first sliding surface (110), which is designed as part of a spherical surface, a support frame (200), which comprises a second sliding surface (210), which is designed as part of a spherical surface, the holding element (100) being supported in the support frame (200) by means of a bearing apparatus such that the first sliding surface (110) of the holding element (100) can be displaced along the second sliding surface (210) of the support frame (200) about the first and second axis (X, Y), an adjusting apparatus (300), which has a positioning component (301) and a first moving apparatus (310) and a second moving apparatus (320), which are each arranged on the positioning component (301), which is mechanically connected to the holding element (100) by means of a connecting element (400), wherein the connecting element (400) passes through the support frame (200) via an opening (220), wherein the connecting element (400) is designed to transmit a movement of the positioning component (301) to the holding element (100), and wherein the connecting element is designed as a screw means, wherein the positioning component can be brought into a released state and a fastened state, wherein the positioning component can be displaced when in the released state, and the positioning component (301) can be clamped immovably against the support frame when in the fastened state by tightening the screw means.

A receiving device includes a magnetic element having a first ferromagnetic layer, a second ferromagnetic layer, and a spacer layer sandwiched between the first ferromagnetic layer and the second ferromagnetic layer, wherein the first ferromagnetic layer is configured to be irradiated with light containing an optical signal with a change of intensity of the light, and wherein the receiving device is configured to receive the optical signal on a basis of an output voltage from the magnetic element.

A receiving device includes a magnetic element having a first ferromagnetic layer, a second ferromagnetic layer, and a spacer layer sandwiched between the first ferromagnetic layer and the second ferromagnetic layer, wherein the first ferromagnetic layer is configured to be irradiated with light containing an optical signal with a change of intensity of the light, and wherein the receiving device is configured to receive the optical signal on a basis of an output voltage from the magnetic element.

Provided are a light detection element, a receiving device, and a light sensor device. The light detection element includes a magnetic element that includes a first ferromagnetic layer, a second ferromagnetic layer, and a spacer layer interposed between the first ferromagnetic layer and the second ferromagnetic layer, wherein the first ferromagnetic layer is irradiated with light in a direction intersecting a stacking direction of the magnetic element.

Provided are a light detection element, a receiving device, and a light sensor device. The light detection element includes a magnetic element that includes a first ferromagnetic layer, a second ferromagnetic layer, and a spacer layer interposed between the first ferromagnetic layer and the second ferromagnetic layer, wherein the first ferromagnetic layer is irradiated with light in a direction intersecting a stacking direction of the magnetic element.