Display control method and electronic device are provided. The display control method is applied to the electronic device including a first processor, a second processor, and a display controller. The method includes: determining first information based on first data and sending the first information to the display controller when the first processor obtains the first data; dividing by the display controller a display area of the display device into a first display area and a second display area in response to the first information; receiving the first data sent by the first processor and controlling the first data to be displayed in the first display area by the display controller; and obtaining second data sent by the second processor and controlling the second data to be displayed in the second display area by the display controller.

An infinitely expandable display apparatus includes a set board outputting image data, a plurality of display devices connected to one another through an interface circuit based on a cascading scheme to sequentially receive the image data, and an output deviation compensation circuit generating a deviation compensation signal for allowing the image data to be simultaneously output from the plurality of display devices, and transferring the deviation compensation signal to the plurality of display devices.

Systems and methods for dynamically adjusting display content and parameters on a display region are provided. A display manager can control a display environment including a plurality of display regions and can display content items in the display regions. The display manager can identify an event record placed via a client device located in a display zone corresponding to a display region of the display environment. The event record can correspond to an event associated with at least one of the respective content items. The display manager can determine to change a first content item displayed within the display region or a value of a parameter of the display region. The display manager can modify the display region by replacing the first content item with a second content item corresponding to the event associated with the event record or by adjusting the parameter of the display region.

A display includes a plurality of pixel chips, chixels, provided on a substrate. The chixels and the light emitters thereon may be shaped, sized and arranged to minimize chixel, pixel, and sub-pixel gaps and to provide a seamless look between adjacent display modules. The substrate may include light manipulators, such as filters, light converters and the like to manipulate the light emitted from light emitters of the chixels. The light manipulators may be arranged to minimize chixel gaps between adjacent chixels.

In a shared environment, commands affecting the state of an object at a plurality of client devices are assembled in an ordered manner in a command log. In a real-time implementation, commands are immediately applied to a current state of the object at respective client devices, subject to commitment (or reversal) according to confirmation (or not) that the commands have been committed to the command log. In a non-real-time implementation, commands are first presented for commitment in the command log and only after the commands have been so committed in the command log are the commands applied to the current state of an object at the client device.

Systems and methods for receiving an input signal from an input device that corresponds to a movement of a cursor on a display of the first host computer, detecting when the cursor moves to an edge of the display of the first host computer and when the input signal corresponds to a continued movement of the cursor beyond the edge of the display of the first host computer, sending a first control signal to switch the communicative pairing of the input device from the first host computer to the second host computer, and sending a second control signal causing a processor in the second host computer to move a second cursor on the second host computer to a location to simulate a continuous movement of the cursor from the edge of the display of the first host computer to a corresponding edge of a display of the second host computer.

A data processing apparatus includes a first display controller that displays on a first display region of a display an operation screen for an operation of another apparatus connected to the data processing apparatus via a network, and displays on a second display region of the display an operation screen that operates a first object selected from a set of at least one object related to the operation, a memory controller that stores on a memory at a predetermined timing an image of the operation screen displayed on the first display region with the first object associated with the image of the operation screen, and a second display controller that, when a predetermined operation is performed on the first object or the set, displays the image associated with the first object on the display.

Systems and methods for dynamic camouflaging are disclosed. A computer-implemented method can be used with the system including determining, by a computing device, if current environment image data is available for a location of one or more users, and instructing, by the computing device, at least one image-enabled clothing system of the one or more users to display a camouflage image based on the determining. The camouflage image is based on the current environment image data when the current environment image data is available, and the camouflage image is based on historic image data associated with the location of the one or more users when the current environment image data is not available.

A portable computing device may comprise an internal central processing unit (CPU), an internal graphics processing unit (GPU), a communications port to communicate with an external computing device, a first electronic display connected to the internal GPU, a second electronic display connected to the internal GPU, a touch input device to receive touch inputs from a user, and a display mode control unit. The control unit may cause the portable computing device to selectively operate in a dual display operational mode, a direct input operational mode, and an indirect input operational mode.

The disclosure provides a method for optimizing remote display at a client device in communication with a remote desktop. The method generally includes receiving one or more frames for display at the client device, determining that a frame rate of the received one or more frames is less than an expected frame rate and/or a resolution of the received one or more frames is less than an expected resolution, determining that at least one of a local central processing unit (CPU) usage at the client device is less than a CPU usage threshold or a local graphics processing unit (GPU) usage at the client device is less than a GPU usage threshold, applying one or more enhancement techniques to the received one or more frames to produce one or more optimized frames while continuously monitoring the local CPU usage and/or the local GPU usage at the client device, and rendering the one or more optimized frames for display at the client device.