Field serviceable display assemblies are provided. Multiple side assemblies are mounted to a structural framework in a moveable manner, each including a channel located between a transparent layer and an electronic display, which is located behind the transparent layer. A fixed structure is positioned within a cavity located within the structural framework and between the side assemblies. The fixed structure remains stationary when the side assemblies are moved between a closed position where the cavity is enclosed, and an opened position where the fixed structure is exposed to facilitate direct access to electronic components located thereon.

The present disclosure provides a display screen based on LED display panels. The display screen includes a plurality of the LED display panels, at least one installation columns, a plurality of longitudinal reference parts, a plurality of assembling and installation assemblies, and a plurality of power control boxes; several LED display panels arranged in longitudinal direction consist of one group; each group of LED display panels has been longitudinally assembled through longitudinal reference parts arranged close to two sides, of backs of a plurality of LED display panels; two transverse adjacent groups of LED display panels are arranged at two sides of one installation column which is vertically located; The transverse reference part of each assembling and installation assembly and the two adjacent longitudinal reference parts are clasped on back to back sides of the installation columns. The display screen has the advantages of being thin, flexible to use.

A system may include at least one temperature control coil secured to a body of a vehicle in a position proximate a smart display sheet. The temperature control coil is configured to heat and/or cool the smart display sheet to maintain a temperature of the smart display sheet within an operating temperature range. Further, the system may include a control system configured to output instructions to control the temperature control coil.

Disclosed in embodiments of the present disclosure are a flexible circuit board assembly, a display assembly and a display device. The flexible circuit board assembly includes: a first flexible circuit board, including a component part, the component part being provided with components; and a first wave absorbing layer, disposed on the component part and configured to cover the components. The display assembly includes a display module and the flexible circuit board assembly; the display module includes a module body and a second binding part, and the second binding part is configured to be bent to a back surface of the module body; and the first flexible circuit board is located on the back surface of the module body and includes a first binding part, and the first binding part is bound and connected to the second binding part of the display module.

An electronic device, a communication device, and a method enhance thermal energy spreading via thermal spreader layer(s) of a flexible layer assembly extending through a hinge coupling first and second device housings of a configurable housing assembly. The thermal spreader layer is positioned on a surface of a flexible circuit of the flexible layer assembly. The thermal spreader layer has one end thermally coupled to a first structure within the first device housing and another end thermally coupled to a second structure within the second device housing to transfer thermal energy between the first and the second structures. The flexible layer assembly deforms within one or both of a first and second chamber respectively of the first and second device housings when the first and second device housings pivot about the hinge from a closed position to an axially displaced open position.

Provided are a display panel, a display device, and a method for configuring a display panel. The display panel includes a display function layer, a support layer and a storage structure, where the support layer is disposed on one side of the display function layer and is in contact with the display function layer; the support layer includes a first cavity and is connected to the storage structure; and the storage structure is provided with a storage unit and is capable of moving a phase changing material from the storage unit into the first cavity or moving the phase changing material from the first cavity into the storage unit. A heater and a cooler are applied to switch the phase changing material between the solid and the liquid phases.

An electronic device may have a hinge that allows the device to be flexed about a bend axis. A display may span the bend axis. To facilitate bending about the bend axis without damage, the display may include a display cover layer with a flexible portion. The flexible portion of the display cover layer may be interposed between first and second rigid portions of the display cover layer. The display cover layer may also include a layer with self-healing properties. The layer of self-healing material may be formed across the entire display cover layer or may be formed only in the flexible region of the display cover layer. The display cover layer may include a layer of elastomer in the flexible region of the display cover layer for increased flexibility. Self-healing may be initiated or expedited by externally applied heat, light, electric current, or other type of external stimulus.

Disclosed are a flexible display screen and a flexible display device. The flexible display screen includes a flexible display panel and a driver chip, the flexible display panel includes a support portion, a first heat insulation layer, a heat dissipation layer, and a second heat insulation layer which are arranged in sequence along a direction from back to a light-emitting surface, the support portion is provided with a recess, and the driver chip is received in the recess.

Provided is an ambient temperature estimating device, ambient temperature estimating method, program, and system that are able to realize both high robustness and high ambient temperature estimation accuracy. An ambient temperature estimating device includes a neural network, a temperature acquisition unit configured to acquire one or more temperature values inside the ambient temperature estimating device, and a neural network calculator configured to estimate an ambient temperature around the ambient temperature estimating device using the neural network. Input values inputted to the neural network by the neural network calculator include the temperature values acquired by the temperature acquisition unit and a heat source control value for controlling a heat source inside the ambient temperature estimating device.

An electronic device is provided. The electronic device includes a housing, a flexible display including a sliding plate and a bendable section, a multi-bar structure supporting the bendable section, a sensor circuit configured to detect a first state in which at least a part of the bendable section enters an internal space of the housing or a second state in which at least a part of the bendable section is drawn out from the housing, at least one temperature sensor, and a processor. The processor obtains a temperature of one or more heating elements through the at least one temperature sensor in the first state, identifies at least one heating element having a temperature higher than a designated temperature, and controls the at least one heating element having the temperature higher than the designated temperature to operate according to a first execution policy.