A display panel includes a first set of pixels that each include a respective red sub-pixel and a respective green sub-pixel and a second set of pixels that each include a respective blue sub-pixel and a respective green sub-pixel, where the first set of pixels and the second set of pixels are arranged on the display panel such that at least one side of each of the pixels in the first set of pixels is adjacent to at least one of the pixels in the second set of pixels, at least one side of each of the pixels in the first set of pixels is not adjacent to any pixel, and the green sub-pixels are arranged on the display panel such that the green sub-pixels are evenly distributed in the display panel.

An electronic device includes a first housing and a second housing that overlaps the first housing. The electronic device includes a display with a first region and a second region. The electronic device includes a processor configured to control the display to display at least one content. The processor is configured to determine a first content and a second content. The processor is configured to identify that a region of the display is extended. In response to identifying that the region of the display is extended, the processor is configured to change a resolution of the first content to correspond to a size of the extended region of the display while the display is being extended. The processor is configured to change a resolution of the second content to correspond to the size of the extended region of the display after the extension of the display is completed.

A mobile device includes a first display portion, a second display portion and a graphics processor. The first display portion is viewable while the second display portion is obscured when the mobile device is in a retracted configuration. Both display portions are viewable when the mobile device is in an expanded configuration. The graphics processor may be coupled to each display portion and configured to generate a first image for display on: the first display portion when the mobile device is in the retracted configuration; at least one of the display portions while the mobile device is in the expanded configuration; and at least one of the display portions while the mobile device transitions between the retracted configuration and the expanded configuration. The second display portion may be a flexible display material, such as an OLED display and with the first display portion may be a single sheet OLED display.

A display of an electronic apparatus includes first to third display portions that at least partially have flexibility and are integrally configured. The display has a first bending portion at a boundary between the first display portion and the second display portion and has a second bending portion at a boundary between the second display portion and the third display portion. A first hinge portion is relatively rotatably coupled to the first and second display portions. A second hinge portion is relatively rotatably coupled to the second and third display portions. The display is configured to be bendable at each bending portion as a start point in response to rotation of each hinge portion. The first bending portion and the second bending portion do not intersect each other and substantially perpendicularly intersect on extended lines of the first bending portion and the second bending portion.

A display driving device and a display driving method with low power consumption are disclosed. The display driving device with low power consumption includes a source driving circuit, a display content detection circuit and a display timing driving circuit. Pixel switches are disposed between an output terminal of source driving circuit and sub-pixels of panel. The display timing driving circuit is coupled to the source driving circuit and display content detection circuit and used to change driving order according to display information detected by the display content detection circuit to control turn-on times of at least two pixel-switches of the pixel-switches to overlap each other to simultaneously drive at least two sub-pixels of the sub-pixels corresponding to the at least two pixel-switches.

A display device capable of performing image processing is provided. A memory node is provided in each pixel included in the display device. An intended correction data is held in the memory node. The correction data is calculated by an external device and written into each pixel. The correction data is added to image data by capacitive coupling, and the resulting data is supplied to a display element. Thus, the display element can display a corrected image. The correction enables image upconversion, for example.

An electronic device, according to various embodiments of the present invention, comprises: a display comprising a first region exposed on the front surface of the electronic device and a second region accommodated within the electronic device or exposed to the exterior of the electronic device; at least one sensor for detecting a change in the display structure of the display; at least one display processor for controlling the driving of the display; and a main processor, wherein the main processor identifies a display area in which image data is to be displayed on the display, according to the change in the display structure of the display on the basis of sensing information transmitted from the at least one sensor, determines a frame rate of the at least one display processor on the basis of the change in the display area, and drives the display at the determined frame rate.

An electronic device and a driving method of a display panel are provided. The electronic device includes a display panel and a driver. The driver is configured to convert a first image signal into a second image signal, output the second image signal to the display panel, and enable the display panel to display an image frame according to the second image signal. Converting the first image signal into the second image signal includes duplicating the first image signal by n times according to a first direction, and simultaneously scanning m adjacent scan lines to simultaneously drive m adjacent pixel units. The first image signal has a first image resolution of A×B, and the second image signal has a second image resolution of m×n×A×B, where m is a positive integer greater than or equal to 2, n is a positive number, and A and B are positive integers.

A method of supporting divided screen areas and a mobile terminal employing the same are disclosed. The method includes: generating input signals for one of sequentially and simultaneously activating a plurality of user functions; activating the user functions according to generated input signals; dividing a screen into divided screen areas that correspond to activated user functions; and outputting functional view areas associated with the activated user functions to the corresponding divided screen areas.

A mobile device includes a first display portion, a second display portion and a graphics processor. The first display portion is viewable while the second display portion is obscured when the mobile device is in a retracted configuration. Both display portions are viewable when the mobile device is in an expanded configuration. The graphics processor may be coupled to each display portion and configured to generate a first image for display on: the first display portion when the mobile device is in the retracted configuration; at least one of the display portions while the mobile device is in the expanded configuration; and at least one of the display portions while the mobile device transitions between the retracted configuration and the expanded configuration. The second display portion may be a flexible display material, such as an OLED display and with the first display portion may be a single sheet OLED display.