The present disclosure relates to a method and device for detecting ambient light, an electronic device and a storage medium. The electronic device includes: a first screen, the first screen being a foldable flexible screen; multiple light sensors, orientations of light sensing surfaces of the multiple light sensors being different; and at least one processor electronically connected with the first screen and the light sensors respectively and configured to select a target light sensor from the multiple light sensors according to a present state of the first screen and obtain target detection data representing present ambient brightness according to detection data of the target light sensor.

An optical sensor includes a light emitter to emit light, a light receiver to receive the light emitted from the light emitter, a first resin body that covers the light emitter and the light receiver to transmit the light emitted from the light emitter to emit the light outside, and a second resin body that seals the light emitter and the light receiver, in which the second resin body is included inside the first resin body, and the second resin body is harder than the first resin body.

A sensor device having a sensor housing and a printed circuit board coupled to the sensor housing. A light emitting device is coupled to the printed circuit board. The light emitting device has an emitter face defining an emission face area. An aperture plate is coupled to the sensor housing, the aperture plate defines an aperture having an aperture area that is less than the emission face area of the emitter face. The aperture is less than 1 mm from the emitter face wherein the light emitting device is not fixed to the aperture plate. A lens is coupled to the sensor housing, having an optical axis extending through the aperture. The aperture plate is positioned between the lens and the emitter face. Boresighting angle variation across sensor components on a manufacturing line may advantageously be reduced without increased cost associated with active alignment. Irradiance drop-out may also be reduced.

An artifact caused by secondary reflection is reduced. An imaging device according to an embodiment includes: a diffuser (110) that converts incident light into scattered light whose diameter is expanded in accordance with a propagation distance and outputs the scattered light; and a light receiver (132) that converts light diffused by the diffuser into an electric signal.

A sensor arrangement including at least one electro-optical sensor which is secured to a receiving structure of a sensor holder. The electro-optical sensor includes a sensor housing with an optically active sensor layer that is arranged thereon. The optically active sensor layer forms a light-sensitive plane. The sensor holder includes a non-adjustable receiving structure which compensates for a previously determined deviation in shape of the electro-optical sensor from a desired shape.

A photoelectric sensor includes: a placement table configured to allow a workpiece to be placed thereon; a light projecting device including a light emitting element configured to emit light and a converging element configured to converge the light emitted from the light emitting element toward a detection area; and a light receiving device configured to receive the light passing through the detection area from the converging element at a position located on a same plane as the placement table in a direction along an optical axis of the light. The optical axis of the light projected from the light projecting device is set such that the light is incident in a direction perpendicular to an incident surface of the light receiving device and focused on the incident surface of the light receiving device.

Devices and methods for detecting a disinfecting state are described. An example of a sensor device is disclosed to include: a housing; a radiation sensitive material disposed on one or more portions of an external surface of the housing; a sensor configured to measure intensity information associated with ultraviolet (UV) radiation of a first frequency band; a controller configured to record the intensity information, temporal information associated with measuring the intensity information, or both; and a transceiver device configured to transmit and receive radio frequency (RF) signals.

Devices and methods for detecting a disinfecting state are described. An example of a sensor device is disclosed to include: a housing; a radiation sensitive material disposed on one or more portions of an external surface of the housing; a sensor configured to measure intensity information associated with ultraviolet (UV) radiation of a first frequency band; a controller configured to record the intensity information, temporal information associated with measuring the intensity information, or both; and a transceiver device configured to transmit and receive radio frequency (RF) signals.

An automobile antenna assembly including a housing adapted for installation on a roof of an automobile, the housing having a base portion and a fin portion extending from the base portion, a radio antenna disposed within the fin portion, and a photo radiation intensity sensor disposed within the base portion, the photo radiation intensity sensor including a first light detecting element located on a first side of the fin portion and a second light detecting element located on a second side of the fin portion opposite the first side, wherein at least a portion of the base portion is translucent for allowing light to be received by the first and second light detecting elements, the fin portion providing a light barrier between the first light detecting element and the second light detecting element.

A sensor device includes a housing, a substrate positioned within the housing, at least one radiative antenna element positioned upon a first surface of the substrate, and a processing section positioned in a stacked arrangement with the substrate, opposite a second surface of the substrate. The substrate includes at least one interruption configured to allow light entering the housing to pass through the substrate from the first surface through the second surface. The antenna elements(s) is positioned upon the substrate so as to avoid the interruption(s). The processing section includes light-responsive circuitry and is configured such that the circuitry is positioned so as to receive light entering the housing through the at least one aperture. The substrate may be generally circular, substantially rigid, have a substantially certain radius between about three-fourths inch and about four inches, and have a substantially certain thickness between about 0.05 inches and about one-half inch.