A first electronic device with a touch-enabled display establishes a wireless connection with a second electronic device that controls display of a user interface on a second display. The first electronic device displays a first user interface on the touch-enabled display, the first user interface including a first affordance corresponding to first media content. While displaying the first user interface, the first electronic device detects a first user input at a location on the touch-sensitive display that corresponds to the first affordance in the first user interface. In response to detecting the first user input, the first electronic device transmits, to the second electronic device via the wireless connection, instructions enabling display of at least a portion of the first media content on substantially the entire second display controlled by the second electronic device.

The methods and systems disclosed herein provide a server that periodically monitors a user's location using one or more beacons while periodically monitoring hazardous conditions using a variety of electronic sensors, such as thermographic imaging. When the user is within a predetermined proximity of a hazardous condition the server transmits an instruction to an electronic wearable device to present a notification (e.g., haptic, noise, and the like) warning the user of the hazardous condition.

Implementations of the present disclosure include actions of receiving image data of an image capturing a scene, receiving data describing one or more entities determined from the scene, the one or more entities being determined from the scene, determining one or more actions based on the one or more entities, each action being provided at least partly based on search results from searching the one or more entities, and providing instructions to display an action interface comprising one or more action elements, each action element being to induce execution of a respective action, the action interface being displayed in a viewfinder

A method for controlling a mouse pointer on at least two displays is provided. A virtual display layout defines a mutual relative positioning of display areas relating to the at least two displays. The method comprises creating the virtual display area and tracking a position of the mouse pointer within it. Upon the mouse pointer being positioned within an area of any of the display areas, the mouse pointer is displayed. Upon the mouse pointer being positioned outside the area of any of the display areas, but within the virtual display area, a first marker is displayed on a side border of the display in a direction the mouse pointer is positioned within the virtual display area, and a second marker is displayed on at least one other side border of another display in a direction the mouse pointer is positioned within the virtual display area.

A multi-screen display control device is shown, which is linked to a host through a universal serial bus (USB) port to receive image data from the host, and uses a plurality of high-definition multimedia interface (HDMI) ports to output a plurality of HDMI sub-images to a plurality of screens. The multi-screen display control device has a USB hub that couples the USB port to a plurality of graphics processing units (GPUs), so that the GPUs generate the HDMI sub-images based on the image data transferred from the host via USB communication technology.

The present invention relates generally to an LED sign system use on roadways, and more particularly to a LED sign system for use on roadways with a redundant controller.

A display system includes a first display device having an active display region having individually controllable pixels, a sensor to generate information that is useful for determining a position of the first display device relative to a second display device, and a display controller to determine the position of the first display device relative to the second display device based on the information generated by the sensor. The display controller determines an image to be shown on the first display device based on the position of the first display device relative to the second display device.

A display device or an electronic device with high portability and browsability is provided. A display device which includes two display panels that overlap with each other and in which the area of a portion where the two display panels overlap with each other is variable is provided. The larger the area where the two display panels overlap with each other is, the smaller the display device becomes. The first display panel includes a first region that performs display. The second display panel includes a second region that performs display, and a third region that is adjacent to the second region and transmits visible light. When the third region overlaps with the side of a surface which performs display of the first region, display can be performed using a seamless large display region.

A display control system includes a plurality of display devices and a display controller (display device). The display controller generates a graphics command for each frame, and attaches, to the graphics command, time stamp corresponding to an order of generation of the graphics command. Each of the plurality of display devices: acquires the graphics command; performs, in parallel, first processing of acquiring only the time stamp attached to the graphics command in the order of generation and second processing of performing rendering processing based on the graphics command in the order of generation and acquiring the time stamp attached to the graphics command based on which the rendering processing is performed; and when a difference between the time stamp acquired in the first processing and the time stamp acquired in the second processing exceeds a predetermined threshold value, performs reduction processing for reducing a load on the rendering processing.

A screen projection control method and an electronic device are provided. The screen projection control method includes detecting that a first electronic device and a second electronic device are connected with each other through a physical bus and confirming screen projection reference parameters based on the second electronic device and the physical bus; establishing a network link between the first electronic device and the second electronic device; obtaining multimedia data to-be-outputted by an output unit of the first electronic device; and transmitting the multimedia data to the second electronic device using the network link based on the screen projection reference parameters to allow the second electronic device to output the multimedia data.