A display device includes a display driver configured to generate a data signal based on input image data, and a display panel configured to display an image in a display area based on the data signal. The input image data includes position information of the image, the display driver updates at least a portion of the position information included in the input image data corresponding to at least a partial area of the display area and provides the data signal including an updated position information during a frame period in which no new input image data is received, and the image corresponding to the partial area is updated in the display area based on the updated position information during the frame period.

The present teaching relates to method, system, medium, and implementations for LED display. A first signal is received that signals a timing for a next data transfer. In response to the first signal, a bit-based image block stored in a memory is transferred, via a bus connected thereto, to one of a pair of alternate buffers pointed to by a write buffer pointer, which is subsequently toggled to point to another of the pair of alternate buffers. A second signal is received that signals a timing for refreshing the LED display. In response to the second signal, the bit-based image block is retrieved from the one of the pair of alternate buffers pointed to by a read buffer pointer, which is then toggled to point to the other of the pair of alternate buffers. The lights of the LED display are then refreshed in accordance with control signals generated based on the bit-based image block.

A vehicle analysis environment includes one or more display screens, such as a display screen wall or an array of display screens. While a vehicle is in the vehicle analysis environment, a vehicle analysis system renders and displays one or more vehicle sensor calibration targets and/or one or more simulated events on the one or more display screens. Vehicle sensors of the vehicle capture sensor data while in the vehicle analysis environment. The sensor data depict the vehicle sensor calibration targets and/or the simulated events that are displayed on the one or more display screens. The vehicle can output actions based on the simulated event and/or can calibrate its vehicle sensors based on the vehicle sensor calibration targets.

Disclosed is a multi-device system running a single operating system, which comprises a first device and a second device. The first device comprises a central processing unit (CPU), a first display unit and a first communication unit. The second device comprises a second communication unit, a microcontroller and a second display unit. The first display unit displays an interface for a first user to operate. Based on the data transmission between the first communication unit and the second communication unit, the CPU, via the microcontroller, indirectly drives the second display unit to display another interface for a second user to operate. According to the operations made by the first user and the second user, the first display unit and the second display unit respectively display different interfaces. From the first user's perspective and the second user's perspective, they are operating two independent operating systems.

This disclosure provides methods, devices, and systems for data synchronization. The present implementations more specifically relate to adjusting a rate at which display updates are output to a digital display based on an activity level associated with the digital display. For example, digital displays that render images with relatively little motion or user engagement may be associated with lower activity levels, whereas digital displays that render images with more significant motion or user engagement may be associated with higher activity levels. In some aspects, an adaptive display interface may dynamically increase the rate at which display frames are output to a display when the activity level increases and may dynamically decrease the rate at which display frames are output to the display when the activity level decreases.

One embodiment provides a graphics processor device that includes circuitry configured to detect a connection of a second display device to a display subsystem of the graphics processor while a first display device of the graphics subsystem is active, write pre-determined pixel data to a reserved portion of memory associated with the display subsystem, configure timings for the second display device while resources allocated to the first display device remain available to the first display device, display the pre-determined pixel data from the reserved portion of the memory on the second display device during reallocation of the resources of the display subsystem to enable output the framebuffer data to the second display device, and transition the second display device from the display of the pixel data in the reserved portion of the memory to the display of the framebuffer data after resources of the display subsystem are reallocated.

A foldable display is disclosed. In one aspect, the foldable display includes a foldable display panel including first to fourth regions adjacent to each other. The foldable display also includes a first support located on a rear surface of the first region and a second support located on a rear surface of the fourth region. The foldable display panel is configured to be arranged in a first configuration in which the foldable display panel is unfolded and a second configuration in which the foldable display panel is folded so that the first support supports the first and second regions and the second support supports the third and fourth regions.

A monitor display system includes a computing device that is coupled to a collection of dissimilar monitors and a display manager that is coupled to the computing device. The display manager has an image generator that generates an image for the collection of dissimilar monitors and also has a pixel density normalizer that is coupled to the image generator and provides an alignment of the image across the collection of dissimilar monitors. A method of managing a display image is also included.

Examples disclosed herein relate to a computing device. In one aspect, the computing device may include a housing including a first point and a second point spatially separated from each other, a first and second wireless communications modules, and a controller. A first waveguide may couple the first point to an input of the first wireless communications module, where an output of the first wireless communications module may be coupled to an input of the controller. A second waveguide may couple the second point to an output of the second communications module, where an input of the second communications module may be coupled to an output of the controller.

Provided is a display device. The display device includes a display panel that includes a first display region and a second display region, a data driving circuit configured to drive a plurality of data lines, a scan driving circuit configured to drive a plurality of scan lines, and a driving controller configured to control the data driving circuit and the scan driving circuit so as to operate the first display region and the second display region at different frequencies when an operation mode is a multi-frequency mode, wherein the driving controller changes the operation mode to a normal mode when a difference between an image signal of a current frame of the first display region and an image signal of a previous frame of the first display region is equal to or greater than a reference value during the multi-frequency mode.