This application discloses a display method for a foldable screen, applied to an electronic device including a foldable screen. The foldable screen can be folded to form at least two screens, and the at least two screens may include a first screen and a second screen. The method includes: When the foldable screen is in an expanded state, the electronic device displays a first interface of a first application in full screen on the foldable screen. The first interface includes an image captured by a camera. When detecting that the foldable screen changes from the expanded state to a half-folded state, the electronic device displays a second interface on the first screen. In this way, a user can conveniently perform photographing, video calling, live broadcasting, or the like without holding the electronic device steady with both hands.

The present disclosure relates to methods and apparatus for display processing. Aspects of the present disclosure can communicate an image to multiple display panels, where the multiple display panels include a first display panel and a second display panel. Further, aspects of the present disclosure can divide the image between the first display panel and the second display panel. Additionally, aspects of the present disclosure can scale at least one of a first portion of the image or a second portion of the image to at least one of the first display panel and the second display panel. Aspects of the present disclosure can also display at least one of the scaled first portion of the image or the scaled second portion of the image on at least one of the first display panel or the second display panel.

The present disclosure describes one or more communities of components (e.g., comprising one or more sensors and/or transceivers) that are configured to automatically locate and/or self-locate their members. The community of components includes a plurality of stationary components, and may include at least one transitory component.

A display method includes, determining a first target value by correcting a first luminance value representing luminance at a first position in a first image based on a second luminance value representing luminance at a second position in the first image, displaying, by the display apparatus, on the display surface a first corrected image generated by correcting the first image in such a way that a luminance at the first position in the first image becomes the first target value, displaying, by the display apparatus, on the display surface a third corrected image generated by using a changed first target value obtained by changing the first target value based on a second target value based on a fourth luminance value representing luminance at a fourth position in the second image, when the second target value is smaller than the first target value.

A modular display system for a vehicle is disclosed. The system includes a plurality of display units that may be arranged along an exterior of the vehicle in different orientations. The system offers a modular, scalable, accessible, and simplified approach to exterior displays for automated and other types of vehicles. The displays, being modular, are not tied to the specific mounting location on the vehicle's exterior. The image data for each display is rotated based on the orientation of the display as installed which is identified by reference to the distinct pin connections of each display's control port.

A captured scene captured of a live action scene while a display wall is positioned to be part of the live action scene may be processed. To perform the processing, image data of the live action scene having a live actor and the display wall displaying a first rendering of a precursor image is received. Further, precursor metadata for the precursor image displayed on the display wall and display wall metadata for the display wall is determined. An image matte is accessed, where the image matte indicates a first portion associated with the live actor and a second portion associated with the precursor image on the display wall in the live action scene. Pixel display values to add or modify an image effect or a visual effect are determined, and the image data is adjusted using the pixel display values and the image matte.

An architecture and method of operation is described for a modular display utilizing wireless mesh networked individual display modules. A controller acts as a master node in the mesh network and sends image data to each individual display module. Each display module acts as a node in the mesh network, asynchronously processes received image data into a memory buffer, and periodically updates the display output to maintain a seamless display.

A display system and methods; in general, a plurality of display sub-assemblies collectively creating a viewing plane. Each display sub-assembly having a plurality of light emitting elements on a substrate with a plurality of substantially equal pixel gaps between light emitting elements. Bend gaps are provided between pixels that enable the display sub-assemblies to bend thereby creating a curved viewing plane. A mobile LED panel display may be formed of a plurality of LED display modules having a plurality of pixels, four or more casters, a battery powered supply, a media player (electrically communicating with the plurality of display modules for controlling the display of images on the LED panel display, and a removable content storage device and; thus, functions as a rugged, light weight, battery powered display to inform customers and passers-by about product and service offerings via a rugged person size mobile light weight battery powered display.

In various implementations, a method of presenting video streams at a head-mountable device (HMD) includes generating a first video stream at a first frame rate for a first display portion. In some implementations, the first frame rate indicates a rate at which frames are presented by the first display portion. In various implementations, the method includes generating a second video stream at a second frame rate for a second display portion. In some implementations, the second frame rate indicates a rate at which frames are presented by the second display portion. In some implementations, the second frame rate is within a threshold relative to the first frame rate. In various implementations, the method includes temporally shifting the second video stream relative to the first video stream so that a majority of refresh times of the first display portion are different from refresh times of the second display portion.

A mobile terminal (20), and in particular, a mobile terminal (20), a combined terminal device (30) and a method for splicing control of mobile terminals (20). For a splicable mobile terminal (20), according to a state determination instruction, the mobile terminal (20) is caused to selectively enter a master operating state or a slave operating state; when the mobile terminal (20) operates as a master, a display partitioning unit (a2) partitions the display content of the master according to the display screen resource of individual mobile terminals (20) in a combined terminal device (30), to obtain a plurality of pieces of partitioned display data corresponding to a plurality of the mobile terminals (20) in the combined terminal device (30), and sends corresponding partitioned display data to slaves; and in a case in which the mobile terminal (20) acts as a slave, upon reception of the partitioned display data from the master, a display switching unit (a3) displays the received partitioned display data. The content displayed by the master can be displayed by the slaves, and when there are a large number of slaves, the content can be displayed to a user on a relatively large screen composed of a plurality of slaves, satisfying people's demand for a large display area.