In some implementations, a computing device can perform multi-display alignment through observed user interactions. The computing device can receive user input aligning a first alignment object on a first display device with a second alignment object on a second display device. The computing device can align the display buffers for each display device based on the positions of the alignment objects in each display buffer corresponding to each display device. The computing device can align display buffers based on observed movements of graphical objects between multiple display devices. When display buffers corresponding to the display devices are misaligned, the user may correct the path of a graphical object when moving the graphical object between display devices. The computing device can detect the correction and align the display buffers of the display devices so that graphical objects are presented at the appropriate locations when moved between the display devices.

An embodiment of the present disclosure provides an electronic device and a display method thereof. The electronic device comprises: a touch processor and a display driver. The touch processor is configured to generate touch information. The display driver is coupled to the touch processor and configured to: receive the touch information sent by the touch processor; send first indication information to the touch processor when the electronic device is in a first operation mode, the first indication information indicating that image data to be displayed is determined by the display driver; determine first image data according to the first operation mode and the touch information; and drive a display screen to display according to the first image data.

An electronic device (e.g., smartphone) can be connected to an external display device, allowing the electronic device to display content on the external display device. The external display device can be a standalone display device or be part of another electronic device (e.g., a laptop or tablet). The electronic device supports multiple input styles including a gesture-based input style and a non-gesture-based input style. The electronic device adapts to the external display device by using the gesture-based input style if the external display device is touch enabled and using the non-gesture-based if the external display is not touch enabled. Additionally or alternatively, the external display device adapts to the input style being used by the electronic device by displaying an augmentation bar associated with the content and supporting the non-gesture-based input style when the external display device detects that the electronic device is using the gesture-based input style.

A smart cover for an electronic device is provided. An electronic device includes a main display device, and a cover operatively coupled to the main display device. The cover incudes an inner surface and an outer surface, the inner surface and the outer surface of the cover include an electronic cloth-based material. The electronic cloth-based material is configured to display content on the inner and outer surfaces of the cover.

An electronic device, such as held device, having a display and camera, displays a user interface that includes a user interface object displayed at a first size; detects, via the camera, a change in distance between a user of the electronic device and the electronic device; and in response to detecting the change in distance between the user the electronic device and the electronic device, changes size of the displayed user interface object.

An electronic device includes a display panel and image processing circuitry. The image processing circuitry receives input image data corresponding to an image to display on the display panel, modifies the input image data by executing a first context task (e.g., lower priority task), and receives a context switch request. The image processing circuitry also pauses modification of the input image data by pausing execution of the first context task and then switches to modifying the input image data by executing a second context task (e.g., higher priority task).

A smart cover for an electronic device is provided. An electronic device includes a main display device, and a cover operatively coupled to the main display device. The cover incudes an inner surface and an outer surface, the inner surface and the outer surface of the cover include an electronic cloth-based material. The electronic cloth-based material is configured to display content on the inner and outer surfaces of the cover.

Systems and methods for providing continuity of audio and/or video (A/V) presets across different contexts are described. In an embodiment, an Information Handling System (IHS), may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: identify a first audio or video setting used by a first audio or video device in a first context; normalize the first audio or video setting into a normalized setting; in response to a determination that the IHS is in a second context, translate the normalized setting into a second audio or video setting; and apply the second audio or video setting to a second audio or video device.

A vehicle display control device, includes a memory; and a processor coupled to the memory. The processor is configured to cause a display unit provided in a vehicle cabin to display an inducement image requesting that an occupant grip a steering wheel in a case in which it is necessary for the occupant to grip the steering wheel, and cause the display unit to display the inducement image more prominently in a case of requesting that the occupant grip the steering wheel before the vehicle switches from an autonomous driving mode to a manual driving mode as the vehicle is continuing to drive autonomously, than in a case of requesting that the occupant continue to grip the steering wheel as the vehicle is continuing to drive autonomously.

A system may include a display and a processor communicatively coupled to the display. The processor may be configured to: output, to the display, a first view of an airport moving map (AMM) having a first map range, the AMM depicting a location of an aircraft on an airport surface; receive aircraft state data and airport surface data; based at least on the aircraft state data and the airport surface data, change the first view of the AMM having the first map range to a second view of the AMM having a second map range; and output, to the display, the second view of the AMM having the second map range.