An electronic device is disclosed. A foldable electronic device according to one embodiment disclosed in the present document can comprise: a foldable display; a first sensor circuit for sensing the folding of the foldable electronic device; a second sensor circuit for sensing the holding, by a user, of the foldable electronic device; a processor functionally connected to the display, the first sensor circuit and the second sensor circuit; and a memory functionally connected to the processor. The memory can store instructions for enabling, when executed, the processor to display contents through the display, display the contents on a two-page basis through the display, when the folding of the foldable electronic device at a predetermined angle is sensed using the first sensor circuit, and display, in a first luminance, a first page of the two pages displayed through the display and display a second page in a second luminance, when the holding of the foldable electronic device for a predetermined time by one hand is sensed using the second sensor circuit. Additional various embodiments identified through the specification are possible.

An image processing method that generates high-resolution image data from low-resolution image data and an image receiving apparatus that is operated by the image processing method are provided. In the image processing method that generates high-resolution image data from low-resolution image data, the low-resolution image data is divided to generate a plurality of first image data, among the plurality of first image data, one of two adjacent image data is second image data, and the other is third image data. Surroundings of the second image data are supplemented with pixel data to generate fourth image data. The pixel data includes part of the third image data. A convolutional neural network using the fourth image data as an input is implemented, fifth image data is output from the convolutional neural network, and a plurality of the fifth image data is combined to generate high-resolution image data. The image receiving apparatus is operated by the image processing method.

Disclosed are a foldable display device capable of fixing a screen by means of folding a display and a method for controlling the foldable display device. The foldable display device according to the present specification comprises a display unit having first and second display regions separated spatially or visually by being folded; a folding sensor unit for outputting a status signal regarding the degree to which the display unit is folded; and a control unit. The control unit can execute a first mode in which the entire screen displayed on the display unit in a fully open state is controlled, and a second mode in which, when the state changes from the fully open state to an intermediately folded state, the screen of the display region in which the touch of a user is sensed is controlled from among the first and second display regions. According to the present specification, the user can verify simultaneously two desired areas of the screen of the same content. Accordingly, the inconvenience of having to scroll back and forth on the screen can be reduced.

System, method, and computer product embodiments for efficiently casting interactively-controlled visual content displayed on a first display screen to a second display screen. In an embodiment, the computing device sends the visual content displayed on the first display screen to a multimedia device for displaying on the second display screen. Upon receipt of an instruction that visually manipulates how the visual content is displayed on the first display screen, the computing device generates a command representative of the received instruction. The command may specify a positional relationship between the center of the first display screen and the visual content displayed on the first display screen. Then, the computing devices sends the command to the multimedia device that causes the second display screen to display the visual content according to the positional relationship.

The method includes the steps of: a) acquiring a display resolution of an external monitor; b) acquiring screen pictures of application pages of a smartphone; c) determining a quantity of screen divisions of the external monitor according to information acquired in step b); d) resizing the screen pictures acquired in step b) to match one of the screen divisions according to the display resolution; e) combining the screen pictures resized in step d) into an integrated screen picture with multiple screen divisions; and f) displaying the integrated screen picture on the external monitor.

A multi-window user interface (UI) is presented in various configurations and operational uses to leverage the relatively large display canvas afforded by large screen display devices such as 4K or 8K displays. Along with the various “Multiview” aspects, content delivery techniques, content selection techniques, and level of service techniques also are presented.

In a projected architecture system, a mobile device may be responsible for providing the video that is displayed on a vehicle's infotainment system's display. The resolution and/or aspect ratio of the remote display may not be supported by the mobile device. An encoder, based on the display resolution, may render one or more video frames that a decoder coupled to the infotainment system can scale to a resolution compatible with the remote display.

An electronic device is provided. The electronic device includes at least one memory storing instructions, a display, and at least one processor. The at least one processor is, when executing the instructions, configured to display a first screen in a first region using the display, while displaying the first screen in the first region, receive a specified input, and in response to receiving the specified input, display at least a portion of the first screen in a first sub region included in the first region and display a second screen and a third screen in a second sub region, which is included in the first region, is disposed beside the first sub region, and has an area smaller than the area of the first sub region.

A method and system is implemented at an electronic device for displaying output from an application on a fixed orientation display. The electronic device includes a display module and an application. The application sends a request to display output from the application in a second orientation with second dimensions, and receives from the electronic device a notification that a display associated with the electronic device is a fixed orientation display with a first orientation and first dimensions. The application then obtains application data verifying that it is able to scale the output for displaying in an orientation and dimensions different from the requested second orientation and second dimensions, and determines optimal dimensions to display the output from the application based on the first orientation and first dimensions associated with the fixed display. The electronic device then scales output data to match the determined optimal dimensions.

The present disclosure relates to a display device capable of reducing a stress cumulative deviation and preventing image sticking with respect to a boundary between first and second display areas separately driven according to the shape and use environment of a display panel, and a display device may include: a panel displaying an image through a display area composed of a plurality of pixels and having a variable shape; a panel driver for driving the panel; and an image processor for dividing the display area into a first display area and a second display area when the shape of the panel is changed, determining a boundary neighboring region including a first boundary neighboring region and a second boundary neighboring region, and modulating data corresponding to the boundary neighboring region using a result of analysis of an image corresponding to the boundary neighboring region.