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.

A battery interconnect assembly includes, among other things, at least one first sense lead operably coupled to a structure on a first side of an array of battery cells, and at least one second sense lead operably coupled to a structure on a different, second side of the array. The assembly further includes a multi-port connector configured to communicate signals from both the at least one first sense lead and the at least one second sense lead. A battery monitoring method includes, among other things, communicating signals from a plurality of sense leads through a multi-port connector. At least one of the sense leads is operably connected to a first structure on a first side of a battery array, and least one of the sense leads is operably connected to a second structure on a different, second side of the battery array.

A flexible electronics assembly including a substrate including one or more dielectrics. A cavity is formed within the substrate. A first ground plane is secured to the substrate. One or more stress channels are formed through one or more portions of the substrate and the first ground plane. An electronics component is disposed within the cavity.

This wiring module includes: a wiring substrate; a base portion at which the wiring substrate is placed; and an adhesive layer configured to adhere the wiring substrate to the base portion, wherein the wiring substrate includes: a land portion configured to have a power generating element mounted thereto; and a wire portion configured to be electrically connected to the power generating element, the adhesive layer has: a land adhesion region configured to adhere the land portion to the base portion; and a wire adhesion region configured to adhere the wire portion to the base portion, and a width of the wire adhesion region is smaller than a width of the land adhesion region.

There are provided a display device and a method of manufacturing the same. The display device includes a display panel and a window disposed on the display panel. The window includes a first sub-window and a second sub-window and a touch sensor disposed between the first sub-window and the second sub-window.

A lighting device 1 includes a circuit board that is long and flexible, light emitters mounted in a row on the circuit board, and an elongated cover. The cover includes (i) a translucent member that is made of translucent soft material and that covers the circuit board and the light emitters, and (ii) a phosphorescent member containing a phosphorescent material that is to be excited by light emitted by the light emitters. The phosphorescent member is arranged on a second area portion of the cover other than a first area portion of the cover that is located in an emission direction of light from each of the light emitters and a luminous intensity is equal to or greater than a standard luminous intensity in the emission direction.

An UV-C device may include several UV-C light sources (e.g., UV-C LEDs) and such UV-C LEDs may have UV-C reflecting structures arranged to direct UV-C in a particular direction and at a particular size and shape. Doing so may, for example, increase the UV-C in a particular direction or working area. A UV-C generating device may be utilized in an air duct to sterilize air through that air duct. A UV-C generating device may, for example, be utilized to increase the amount of UV-C that enters a UV-C fiber optic tube. A UV-C generating device may be utilized, for example, to inactivate one or more virus (e.g., one or more different viruses and/or one or more claves of the same virus) and a UV-C inactivated virus may be utilized as a vaccination. A facility may be provided that received strains from the same clave and/or different claves and that UV sterilizes (e.g., UV-C sterilizes) the strains and combines the strains into a combinational UV-C vaccination of multiple UV-C inactivated strains.

A UV-C generator is provided where multiple UV-C LEDs are provided around a work area (e.g., a tube) in order to sterilize contaminants in that work area (e.g., virus and/or bacteria) to provide a sterilization device for substances in, or flowing through, the work area. The tube may gates to change the speed and/or direction of a flowing working substance and may have a spiraling channel in the tube such that the length of travel in the spiraling channel is longer than the tube. Such UV-C generator devices may be utilized, for example, to sanitize air flowing through devices such as a ventilator or face mask.

A UV-C generator is provided where multiple UV-C LEDs are provided around a work area (e.g., a surface) in order to sterilize contaminants in that work area (e.g., virus and/or bacteria). The sterilization device can be utilized, for example, in a wand, broom, set distance surface sterilizer, hand sanitizer, foot sanitizer, conveyer sanitizer, or any other sanitizer. Mating structures may be included to mate multiple devices to extend work area that may be impacted. The devices may be portable and may include one or more rechargeable batteries.

A hands-free object sanitization system is provided where multiple UV-C LEDs are provided around a work area (e.g., a surface) in order to sterilize contaminants located on objects placed in that work area (e.g., virus and/or bacteria). Objects may travel through the work area without direct human intervention so that a hands-free sanitization system is provided. For example, objects may be dropped through a working area so that gravity provides a transport force through that working area.