Provided are a method, apparatus and device for compensating a display screen and a display screen driver board, which belong to the technical field of display. The method comprises: according to the texture complexity of a screen to be displayed by each region (10) among a plurality of regions (10), determining a conversion matrix corresponding to pixels in each region (10)(101); and performing grayscale compensation on pixel points of the screen in each region (10) by using the conversion matrix corresponding to the pixels in each region (10) to obtain a compensated grayscale (102); wherein the compensated grayscale is configured to control the screen display of the plurality of regions (10), so that the uniformity of the screens displayed in a first screen is higher than the uniformity of the screens displayed in a second screen, and the texture complexity of the first screen is lower than the texture complexity of the second screen, the first region and the second region each being one among the plurality of regions (10).

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.

Displays, systems, and methods may be utilized in applications including, but not limited to, projectors, head-up displays, and augmented reality (AR), mixed reality (MR), and virtual reality (VR) systems or devices, such as headsets or other near-eye devices or systems. Tiled or Tile-able displays and methods, in accordance with the present invention, provide displays of varying sizes, and as such, a Tiled or Tile-able display is configured to accommodate the display size needed for various wearable and mobile devices that require or incorporate displays.

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.

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.

The display system has a three-dimensional and curved display surface made up of a single electronic display screen or several joined electronic display screens, the display surface having at least one main zone dedicated to a pilot and suitable for being located in front of said pilot, the main zone being substantially planar or concave, and at least one lateral zone associated with each main zone, each lateral zone being concave and laterally extending the associated main zone.

Mechanisms to allow a user to flexibly display visual content on multiple display devices connected to a computer. Each of the multiple displays may be configured to display a portion of visual content from a computer desktop or from an external content source. Each portion of visual content to be outputted may first be enhanced, such as via magnification, before being displayed on one of the multiple display devices. The user may be provided with a first control that enables the user to adjust a portion of visual content displayed on a first display device independently of a portion of visual content displayed on a second display device. A second control may also be provided that enables the user to adjust the portion of visual content displayed on the second display device independently of the portion of visual content displayed on the first display device.

The invention relates to a method for operating an interactive visibility screen on a transparent pane of a pane device, in particular in a motor vehicle. The visibility screen is generated by means of a display unit of the pane device on the pane by pixel-wise fade-in of opaque image points, wherein the image points form a coherent visibility screen area. In the method, an operational action by the user is first detected by means of a detection device, which comprises a selection of a setting range and a movement relative to the pane. Subsequently, an expansion of the visibility screen area at the setting range is set as a function of the detected movement by means of a control device.

A light emitting diode (LED) module includes an integrated substrate, the integrated substrate including a plurality of LEDs; a glass substrate; and a signal wiring layer provided on the glass substrate. The signal wiring layer includes a plurality of signal electrodes configured to supply a data signal to the plurality of LEDs. The LED module further includes a conductive pattern provided on at least one surface of the integrated substrate, and connected to a ground.

The present disclosure provides an LED display device. The LED display device divides each of LED modules into a plurality of unit blocks. In each of the unit blocks, a display controller transmits image data to be processed in parallel to the corresponding data driver at the same time, and transmits logic signals to the corresponding gate driver, thereby driving the corresponding data driver and then turning on the corresponding LEDs. Therefore, the speed processing the image data of each unit block can be improved, to enhance the visual refresh rate.