The present disclosure relates to the field of display technologies, and in particular, to a shift register circuit and a display device. The shift register circuit may include a plurality of GOAs for outputting scan signals to a plurality of pixel driving circuits and a plurality of EOAs for outputting control signals to the plurality of pixel driving circuits, where the GOAs and the EOAs are alternately arranged in a straight line.

Provided herein may be a display device and a method of controlling a plurality of display devices. The method may include displaying, on a first display device, a first image including a first partial image, a second partial image, and a third partial image, transmitting, by the first display device, a second image including a fourth partial image corresponding to the first partial image, a fifth partial image corresponding to the second partial image, and a sixth partial mage corresponding to the third partial image to a second display device, displaying the second image on the second display device, receiving, by the first display device, a first touch input for a first input interface included in the third partial image, and receiving, by the first display device, a second touch input for at least one of the fourth, fifth partial image, and sixth partial images.

If a distance from a current position to a guide point is less than a predetermined distance, a normal output process and a stop process of a guide image are repeatedly performed. If a priority display request for a guide image is performed, a priority output process of the guide image is performed prior to the stop process. If an interval between the priority output process and the normal output process performed after the priority output process is short, the priority output process continues until the normal output process starts.

An electronic device that includes a display screen and circuitry is provided. The display screen displays map data and a user interface (UI) element. The circuitry receives a first user input, via the UI element. The first user input indicates a geographical region on the displayed map data. The circuitry extracts geo-location information from vehicle data associated with a vehicle. The circuitry further controls a communication of a first portion of the vehicle data with a server based on a first geo-location in the extracted geo-location information of the vehicle data and the indicated geographical region. The first portion of the vehicle data corresponds to the first geo-location.

A dual-screen computing device includes two separate displays that are coupled to an interconnecting hinge. A hinge detector detects movement or position of the hinge, and the positions of the displays may be determined based on the hinge movement or position. The positions of the displays relative to each other may then be used to determine which mode of operation the dual-screen computing device is operating (e.g., tent mode, open, closed, etc.). Additionally, the dual-screen computing device may include various sensors that detect different environmental, orientation, location, and device-specific information. Applications are configured to operate differently based on the mode of operation and, optionally, the sensor data detected by the sensors.

A method includes: transmitting a screen shared by a plurality of apparatuses coupled through a network to the plurality of apparatuses at a given interval; updating the screen based on operation information when receiving the operation information regarding the screen from a first apparatus which an operation right regarding the screen is given among the plurality of apparatuses; and determining, by a processor, the given interval based on comparison between a first index value that represents smoothness of display of the screen in the first apparatus and a second index value that represents smoothness of display of the screen in a second apparatus among the plurality of apparatuses when the operation right is moved from the first apparatus to the second apparatus.

An information processing apparatus includes a communication unit, a display, and a remote operation unit. The communication unit communicates with an external device. The display displays information, and receives an input operation. The remote operation unit remotely operates a screen displayed on the external device. The remote operation unit operates the external device in a state in which at least one operation on the external device are invalidated. In the case where a drawing input operation is performed on the display with the screen displayed on the external device displayed on the display, the remote operation unit validates an operation corresponding to the drawing input operation, among the at least one operation on the external device which have been invalidated.

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.

A method includes: first setting a display range of image data stored in a memory and to be displayed in a display of a terminal device, in accordance with a scroll amount determined based on operational information acquired from the terminal device; measuring a first frequency of update at which a region within the image data is updated in the display range; and second setting, by a processor, based on the first frequency, a second frequency of capture at which partial image data of image data corresponding to the region is captured from the memory when the region is changed from an inside of the display range to an outside of the display range by changing of the display range.

An apparatus, system, or method may wirelessly send an audio component of a multimedia channel to one or more wireless computing devices while a visual component of the multimedia channel is playing on a video monitor. The extracted audio component of the multimedia content may be packetized into data packets and broadcast via a network such that the data packets can be received by the wireless computing devices and the audio component can be played by the wireless computing devices in synchronization with the visual component playing on the video monitor. A channel listing may inform the wireless computing devices what channels are available. A visual content that is not the visual component of the multimedia channel may be displayed on the wireless computing device while an audio component of the multimedia channel is streamed to the wireless computing device. A direction indicator may be displayed on the wireless computing device to indicate the direction of a video monitor playing the visual component. A user of the wireless computing device may request that the visual component playing on a video monitor be set to a user-selected component.