An approach for providing a user interface having a resolution corresponding to a resolution of a high resolution content is provided. The approach allocates at least one partial frame buffer based on a size and a location of a region on a screen of a display on which a user interface (UI) is displayed. The approach displays the UI based on at least one piece of partial graphic data obtained from the allocated at least one partial frame buffer.

A method of luminance compensation includes; generating luminance compensation data based on test image data, each of the test image data corresponding to one gray level, and each of the luminance compensation data including compensation values corresponding to the one gray level, generating intra-plane data based on the luminance compensation data, one of the intra-plane data being generated based on one of the luminance compensation data, generating inter-plane stream data based on the intra-plane data, one of the inter-plane stream data being generated based on data blocks included in the intra-plane data and disposed at a same location within the intra-plane data, and sequentially storing the inter-plane stream data in a memory.

Apparatus, methods, and program products for preventing data snipping are disclosed. One apparatus includes a processor and a memory that stores code executable by the processor. The code is executable by the processor to partition an electronic image into a plurality of graphics frames for display on a display device, wherein each separate graphics frame in the plurality of graphics frames includes a different portion of the electronic image, and transmit each separate graphics frame of the plurality of graphics frames to the display device, wherein each separate graphics frame in the plurality of graphics frames is separately transmitted to the display device for display thereon within each display cycle. Methods and computer program products that perform the operations and/or functions of the apparatus are also disclosed.

The present invention discloses a device and method for controlling zooming-in of an electronic map, a device and method for controlling zooming-out of an electronic map, a device and method for controlling panning of an electronic map, a device and method for computing tiles within a visual region of an electronic map, and a device and method for processing an electronic map tile request queue, wherein the method for controlling zooming-in of an electronic map comprises: determining a target display level to be reached via zooming in when receiving an instruction of zooming in the map, and searching out a plurality of target tiles that need to be displayed in the target display level; selecting a pre-loaded display level based on a relationship between a current display level and the target display level, and searching out pre-loaded tiles corresponding to the target tiles in the pre-loaded display level; acquiring the pre-loaded tiles and the target tiles according to an order of priority, loading and displaying the pre-loaded tiles by zooming in according to a level difference between the pre-loaded display level and the target display level; and after acquiring the target tiles, loading and displaying the target tiles so as to replace the zoomed-in pre-loaded tiles at corresponding positions.

A display unit according to an embodiment of the disclosure includes a substrate, a wiring line and a light-emission section that are provided on the substrate, an insulating layer covering the wiring line and the light-emission section, and provided on an entire surface of the substrate, and a sealing layer provided on an entire surface of the insulating layer, and including a resin material having an oxygen transmission rate higher than a water-vapor transmission rate.

A method for improving application sharing by dynamic partitioning can include partitioning a screen display of an application into grid regions and, in response to detecting that an application image in the plurality of grid regions have changed, offsetting positions of the grid regions, so that the changed portions of the application image are in fewer grid regions using a computer system. The method also can include transmitting image data in the offset grid regions involving the changed portions of the application image and identifications and offset data of the offset grid regions to an application sharing client.

A display controller is provided. The display controller includes n field-programmable gate arrays (FPGAs) (n is an integer greater than 1). A respective one of the n FPGAs includes a first input circuit and an output circuit and a first process circuit connected between the first input circuit and the output circuit. The first input circuit is configured to receive a respective one first sub-image corresponding to the respective one of the n FPGAs. The n first sub-images are combined to form one frame of initial image. The first process circuit is configured to enhance image-resolution of the respective one first sub-image to obtain a respective one second sub-image and the output circuit is configured to deliver the respective one second sub-image corresponding to the respective one of the n FPGAs to a timing-controller.

A central processing unit executes a graphics accelerated operation during a pre-boot basic input/output system (BIOS). The central processing unit initializes multiple protocol scheduler circuitry during an early phase of the pre-boot BIOS. The multiple protocol scheduler circuitry initializes host memory pages, and creates one or more bit block transfer tasklets during the pre-boot BIOS. A graphics processing core executes one of the bit block transfer tasklets, and renders a graphical user interface element for display during the pre-boot BIOS.

In one embodiment, a computing system may write pixel values into a buffer in a tile order. Each writing operation may write a block of pixel values into two memory units. The first memory unit may receive a first half of the block of pixel values. The second memory unit may receive a second half of the block of the pixel values. The system may read a subset of pixel values from the buffer in a pixel row order. Each reading operation may read a second block of pixel values from the two memory units of the buffer. The first memory unit may provide a first half of the second block of pixel values. The second memory unit may provide a second half of the second block of pixel values. The system may output the subset of pixel values read from the buffer via an output data bus.

A display apparatus including a display module and a support module configured to support the display module, wherein the support module includes: a fixed frame configured to support the display module and a link structure disposed between the fixed frame and the display module and configured to rotate the display module through at least a six-bar link structure, so that the display module is easily detachably attached to the fixed frame, thereby shortening a time for an operation of replacing, repairing, or installation of the display module.