A wearable device includes a wearable device main body, a sensor part configured to contact a skin surface of a user of the wearable device, and measure a bio-signal of the user, and a shock absorber that is interposed between the wearable device main body and the sensor part to mechanically connect the wearable device main body and the sensor part, and that is configured to reduce motion transmission between the wearable device main body and the sensor part to permit the wearable device main body to move independently from the sensor part.

In example implementations, an electronic device housing is provided. The electronic device housing includes a display housing, a lifting mechanism, abase housing, and a secondary display. The lifting mechanism is coupled to a side of the display housing. The base housing is coupled to the display housing. The secondary display is coupled to a distal side of the base housing. The lifting mechanism is to lift the secondary display on a rotation of the display housing.

An electronic apparatus includes a first body, a second body, a connection device, a first driving device, a flexible body, and an elastic member. The second body forms an accommodation chamber with the first body. The second body includes an opening. The connection device is connected to the first body and the second body. The second body moves relative to the first body through the connection device. The first driving device is configured to drive the second body to move relative to the first body through the connection device. The flexible body is attached to a first surface of the first body and a second surface of the second body. The first surface and the second surface are located on a same side of the electronic apparatus. The elastic member is arranged in the accommodation chamber. A first end of the flexible body is fixedly connected to the first body.

In one embodiment, a method for managing visual uniformity in a foldable display includes identifying a hinge angle of the foldable display, the hinge angle indicating a degree to which the foldable display is opened or closed; receiving surface curvature data from a plurality of sensors of the foldable display, the surface curvature data indicating a mechanical state of a surface of the foldable display; accessing a plurality of surface maps stored in a display database of the foldable display, each of the plurality of surface maps indicating one or more display settings associated with a respective mechanical state of the surface of the foldable display; retrieving the one or more display settings from the display database based on the hinge angle and the surface curvature data; and causing a plurality of pixels to illuminate using the one or more display settings.

A slide rail mechanism for a retractable screen structure includes a holder assembly including a holder; and a slide rail assembly including a fixed seat fixedly coupled to the holder, a sliding member coupled to a flexible display screen of the retractable screen structure and arranged on the fixed seat and slidable along a first direction, and an elastic assembly having a first end coupled to the fixed seat and a second end coupled to the sliding member. The second end of the elastic assembly and the flexible display screen are driven to move together when the sliding member slides along the first direction relative to the fixed seat.

A display device includes a display module which is foldable and includes a first non-folding area, a folding area and a second non-folding area, in order, a first plate corresponding to the first non-folding area, a second plate corresponding to the second non-folding area and spaced apart from the first plate, and a cover film facing the display module with both the first plate and the second plate therebetween. The cover film includes a first film corresponding to each of the first non-folding area, the folding area and the second non-folding area, the first film attached to each of the first and second plates, and at the folding area, a second film attached to the first film. The display module which is folded disposes the second film between the first film and the first plate and between the first film and the second plate.

An electronic apparatus includes a host, a main display, a keyboard, an auxiliary display, and a supporting mechanism. The main display is pivotally connected to the host. The keyboard is slidably disposed on the host. The auxiliary display is disposed on the host and is arranged side by side with the keyboard. The auxiliary display includes a movable end and a lifting end, the keyboard contacts the movable end, and the movable end is slidably connected to the host. The supporting mechanism includes a first link, a second link, and a third link. The first link is slidably connected to the host and is pivotally connected to the second link. The second link is pivotally connected to the host and is pivotally connected to the third link. The third link is pivotally connected to the lifting end.

The present disclosure provides a touch data processing method, apparatus, device and storage medium. A display content from the second operating system is displayed on a display interface of the first operating system, and after a touch screen on a device where the first operating system is located is rotated by a preset angle, if a touch operation on the touch screen is detected, whether the touch operation is an operation on a display content in the target display area is determined; if yes, touch data corresponding to the touch operation can be sent to the second operating system, so that the second operating system responds to the touch operation. The present disclosure realizes that even if the touch screen on the device where the first operating system is located is rotated, the second operating system can be controlled to respond to the touch operation by touching the touch screen.

A foldable device includes a housing and a foldable display device coupled to the housing. The foldable display device includes a foldable display layer, a foldable glass layer on a first side of the foldable display layer, and a sensing device on a second side of the foldable display layer. The sensing device includes a strain gauge layer. The strain gauge layer includes an array of resistors arranged on a piezoresistive substrate. Changes in resistance levels measured by the array of resistors are used to detect faults such as scratches, punctures, cracks and the like in the foldable glass layer. The foldable device may output an alert in response to detection of a fault in the foldable glass layer.

An electronic device is provided. The electronic device includes a first housing, a second housing, the first housing slidable with respect to the second housing, a flexible display including a first display area and a second display area extending from the first display area and bendable or rollable, a battery disposed in the first housing or the second housing, and a supporting structure supporting at least a portion of the flexible display. The supporting structure includes a first area overlapping the battery and a second area extending from the first area. The first area of the supporting structure has a first thickness, and the second area of the supporting structure has a second thickness larger than the first thickness.