A method and a device for displaying non-standard resolution data are provided. The method includes: reading signal source data and determining whether the signal source data is standard resolution data; in a case that the signal source data is non-standard resolution data, determining whether the non-standard resolution data is already stored in a memory; in a case that the non-standard resolution data is already stored in the memory, displaying the non-standard resolution data; and in a case that the non-standard resolution data is not stored in the memory, storing the non-standard resolution data in the memory and displaying the non-standard resolution data.

In a process of accepting projection by a first device, a second device obtains first information, to adaptively adjust one or more of a frame rate corresponding to a projected interface, a size of an application display region corresponding to a projected interface, display resolution of the second device, or video resolution corresponding to a projected interface. In this way, an image processing resource and a processing capability of the device can be allocated on demand to enhance a projected picture and reduce load of the second device.

An electronic device is described. The electronic device includes a memory. The electronic device also includes a very long instruction word (VLIW) circuit. The VLIW circuit includes an asynchronous memory controller. The asynchronous memory controller is configured to asynchronously access the memory to render different levels of detail. The electronic device may include a non-uniform frame buffer controller configured to dynamically access different subsets of a frame buffer. The different subsets may correspond to the different levels of detail.

In order to solve a problem that conventionally there is no image output apparatus in which a wide-band image can be output in a narrow band, an image output apparatus includes: an accepting unit that accepts first-image information, which is information related to a first image of a first band; and multiple image output units that output second images, each of which is an image of a second band that is narrower than or equal to the first band, using the first-image information, wherein a third image obtained as a result of output of the second images by the multiple image output units is an image of a third band that is wider than the first band. Accordingly, it is possible to provide an image output apparatus in which a wide-band image can be output in a narrow band.

A system for reducing bandwidth and/or reducing power consumed by a display may comprise a display having a background plane and a region of interest plane that may be identified by a gaze tracker. The region of interest may be of a higher quality picture. In some embodiments, the display may be a large panel display and in others a head mounted display (HMD).

The present disclosure relates to a pixel driving circuit for switching display resolution, a driving method thereof, and a display apparatus. The pixel driving circuit comprises: r first data lines and k second data lines, each of the first data lines has a first switch provided thereon, and is connected to at least one of the k second data lines through at least one second switch respectively, and the first switch and the second switch are connected to a signal control unit which is configured to control the first switch to be turned on and the second switch to be turned off when display is to be performed at a first resolution, and control the first switch to be turned off and the second switch to be turned on when display is to be performed at a second resolution.

The present invention relates to a mobile terminal for controlling dynamic resolution, comprising: a display unit for receiving a user input for executing an application including a plurality of objects; a memory for storing setting information displaying, at a first resolution, a screen on the display unit; and a control unit for receiving information on a plurality of resolutions supported by the application, selecting a second resolution, which is the resolution of an execution screen on which the application is executed, on the basis of the first resolution and the plurality of resolutions, configuring the execution screen by synthesizing the plurality of objects with a system UI according to the second resolution, and up-scaling the configured execution screen according to a ratio of the first and second resolutions so as to display the up-scaled execution screen on the display unit. Therefore, dynamic resolution can be controlled.

According to various examples, a first resolution of original display data and a second resolution of a text display may be obtained. In response to a determination that the second resolution is smaller than the first resolution, the original display data may be searched for a relocation area and a bland area. The relocation area may include valid pixels not capable of being displayed on the text display. The blank area may not include valid pixels and may be capable of being displayed on the text display. The blank area may be used to accommodate the relocation area within the text display to generate reconstructed display data, and the reconstructed display data may be outputted to the text display.

A method, system and computer-program product for real-time virtual 3D reconstruction of a live scene in an animation system. The method comprises receiving 3D positional tracking data for a detected live scene by the processor, determining an event by analyzing the 3D positional tracking data by the processor, comprising steps of determining event characteristics from the 3D positional tracking data, receiving pre-defined event characteristics, determining an event probability by comparing the event characteristics to the pre-defined event characteristics, and selecting an event assigned to the event probability, determining a 3D animation data set from a plurality of 3D animation data sets assigned to the selected event and stored in the data base by the processor, and providing the 3D animation data set to the output device.

In an embodiment according to the present disclosure, disclosed is an electronic device including a display, a first housing, a second housing at least partially overlapping and being movable with respect to the first housing, a first conductive region formed or disposed inside the first housing, and a second conductive region formed or disposed inside the second housing so as to at least partially overlap with the first conductive region when the first housing is moved with respect to the first housing, a display in which at least the first region is exposed to the outside of an electronic device through a front surface of the electronic device, and at least one processor in which, when the electronic device is switched from the first state to the second state, a second region extending from the first region of the display is withdrawn from the inside of the first housing and exposed to the outside of the electronic device along with the first region and, when the electronic device is switched from the second state to the first state, is introduced into the inside of the first housing and operatively connected to the display. The at least one processor identifies a capacitance value, based on an overlapped region of the first conductive region and the second conductive region, and determines an externally exposed region of the display, based on the identified capacitance value, and controls the region determined to be exposed outside, to an activated state, and controls the remaining region except the region determined to be exposed outside, to an inactivated state. In addition to this, various embodiments identified through the specification are possible.