Disclosed are a vector diagram generation method and apparatus, and a storage medium, the method being used in an FPGA. The method comprises: acquiring video data of an ultra-high definition video system; on the basis of the video data, generating vector diagram data; acquiring a pre-generated background image of the vector diagram; and, on the basis of the background image and the vector diagram data, generating a vector diagram. The vector diagram generation method and apparatus and storage medium provided in the present disclosure can better implement vector diagram generation of the ultra-high definition video system. (FIG. 1)

An AR system is arranged to display an image stream of an environment with one or more virtual objects, each virtual object being associated with a marker in the image stream. The AR system includes a tracking subsystem arranged to track a first pose of the marker in the image, and inform a frame rendering subsystem, which generates a rendering of the VR object and provides the rendering to the reprojecting subsystem together with information about the first pose of the marker and information identifying a set of pixels included in the VR image. The tracking subsystem further determines a second pose of the marker based on detected movement and informs the reprojecting subsystem about the second pose. The reprojecting subsystem renders an image frame including the image stream of the environment with the rendering of the VR object reprojected in dependence of the second pose.

An apparatus, method, and computer readable medium that access a frame buffer of a graphics processing unit (GPU), analyze, in the frame buffer, a frame representing displayed data, based on the analyzed frame, identify a reference patch that includes an instruction to retrieve content, generate an overlay including an augmentation layer which includes the content, superimpose the overlay onto the displayed data such that the content is viewable while a portion of the base layer is obscured, detect a user input, determine a location of the user input in the augmentation layer, associate the location in the augmentation layer with a target location in the base layer, and associate, within memory, the target location with an operation such that the user input in the augmentation layer activates an input in the base layer.

A computing device includes an image sensor, an IMU, a display, and a processor coupled to the image sensor, the IMU, and the display. The processor is configured to generate a GUI current screen on the display. The GUI current screen includes a background, and foreground GUI elements overlaying the background. The processor is configured to when the IMU generates motion data indicative of movement, render the background to comprise a video image from the image sensor.

A remote operation apparatus is configured to operate in response to a control signal transmitted via a network from a user apparatus connected to a display unit and includes a movable unit capable of changing a posture. The remote operation apparatus includes: a video data acquisition unit configured to acquire video data acquired from a camera disposed in the movable unit; a motion detection data acquisition unit configured to acquire, through a motion sensor, motion detection data representing a change in the posture of the movable unit; and a data transmission unit configured to transmit the acquired video data and the acquired motion detection data to the user apparatus via the network.

A control device of a head-mounted device is provided. The head-mounted device includes an image capturing device configured to capture an environment around a wearer and a display device configured to display an image to the wearer. The control device includes a first acquisition unit configured to acquire a first image captured by the image capturing device, a second acquisition unit configured to acquire a second image used to lead a mental state of the wearer to a target mental state, and a composition unit configured to composite the first image and the second image, thereby generating a third image to be displayed on the display device.

In some aspects, the present disclosure provides a method for high dynamic range (HDR) video rotation. The method includes receiving, by a display processor, an indication that a frame rotation animation process for video playback has been initiated, the display processor comprising a display processor pipeline. The method also includes determining whether the video playback is an HDR format or another format. In response to the determination and receiving the indication: bypassing a loading of the frame rotation animation into a first portion of the display processor pipeline, and loading the frame rotation animation into a second portion of the display processor pipeline if the video playback is in an HDR format.

A video processing device includes a receiver that successively receives input images, each having a prescribed overlapping image superimposed in one or more areas thereof, a compositing image generation unit that successively generates compositing images based on the external information, a video compositing unit that successively generates composite images, a compositing abnormality detection unit that determines whether one or more areas of the composite image have abnormality or not, a comparison unit that compares the one or more areas of the input image with those of the composite image to determine whether or not the respective areas match, if it is determined that the composite image have no abnormalities, and an output control unit that outputs the input image if it is determined that the respective areas match, and outputs the composite image when it is determined that the respective areas do not match.

A method, apparatus and computer program product describing groups of overlays, such as semantically correlated overlays, to background media content. In the context of a method, a group of overlays to background media content is defined by metadata (60). The overlays include semantically correlated overlays having alternative overlays representing content with different levels of detail or overlays providing different choices of content. The method also includes receiving client selection of a respective overlay from a group of overlays (62). In response to the client selection, the method causes the respective overlay to be provided. The respective overlay is received (64) for presentation concurrent with background media content (68).

A display control device includes: a reception unit that receives an input for designating a first point on a first image, which is displayed on a display screen provided in a vehicle compartment and shows a peripheral environment of a vehicle at a first timing; a display processing unit that displays a first display object at the first point; a specifying unit that specifies a second point at which a first target, which is located at the first point, is located on a second image, which shows the peripheral environment of the vehicle at a second timing after the first timing; and an update unit that displays, along with the second image, the first display object at the second point on the second image.