An apparatus for switching media content playback from a first playback device to a second playback device across a plurality of playback devices may include a controller programmed to detect a change in location of a portable device from a first media zone including a first playback device to a second media zone including a second playback device, determining a playback position of currently played media content provided from a first media source to the first playback device, identify a second media source that is available at the second media zone, and control the second media source to transmit the currently played media content to the second playback device to switch playback from the first playback device to the second playback device at the playback position.

A computer-implemented method is provided for capturing one or more image frames of a real-time streaming video using a wrapper module configured to function with a video player. The wrapper module is in electronic communication with a server. The method includes receiving, by the wrapper module, during streaming of the video by the video player, an indication from a user of a current viewing location in the video to initiate image capturing. The method includes capturing, by the wrapper module, one or more image frames from the video based on the indication of the current viewing location. The method also includes transmitting, by the wrapper module, the one or more captured image frames to the server.

A computer-implemented method is provided for capturing one or more image frames of a real-time streaming video using a wrapper module configured to function with a video player. The wrapper module is in electronic communication with a server. The method includes receiving, by the wrapper module, during streaming of the video by the video player, an indication from a user of a current viewing location in the video to initiate image capturing. The method includes capturing, by the wrapper module, one or more image frames from the video based on the indication of the current viewing location. The method also includes transmitting, by the wrapper module, the one or more captured image frames to the server.

A computer readable storage medium has stored thereon a prerecorded video experience container. The prerecorded video experience container includes a prerecorded video file that displays visual content, an executable experience which upon execution enables presentation of additional content associated with the prerecorded video file, and an interactive region of the prerecorded video file, wherein the interactive region of the prerecorded video file is associated with the executable experience such that a user interaction with the interactive region executes the executable experience. The prerecorded video file is displayed in response to a selection of the prerecorded video experience container. The executable experience associated with the prerecorded video file is executed in response to identifying an interaction with the interactive region. The additional content associated with the prerecorded video file is displayed in response to executing the executable experience.

In various examples, cloud computing systems may store frames of video streams and metadata generated from the frames in separate data stores, with each type of data being indexed using shared timestamps. Thus, the frames of a video stream may be stored and/or processed and corresponding metadata of the frames may be stored and/or generated across any number of devices of the cloud computing system (e.g., edge and/or core devices) while being linked by the timestamps. A client device may provide a request or query to dynamically annotate the video stream using a particular subset of the metadata. In processing the request or query, the timestamps may be used to retrieve video data representing frames of the video stream and metadata extracted from those frames across the data stores. The retrieved metadata and video data may be used to annotate the frames for display on the client device.

The windowless prototypes of various evacuated tube transportation (ETT) based transportation systems, such as Hyperloop-based transportation systems, has the negative feel of an enclosed space. The lack of any kind of outside reference, the unknown sounds and the tremendous speed of the capsule/pod would surely cause anxiety with several passengers. A representation of the outside world shown within the pod/capsule using augmented windows alleviates this claustrophobic environment. At least for the closest passenger to the window, the illusion of looking out on a landscape is achieved using such augmented windows.

The windowless prototypes of various evacuated tube transportation (ETT) based transportation systems, such as Hyperloop-based transportation systems, has the negative feel of an enclosed space. The lack of any kind of outside reference, the unknown sounds and the tremendous speed of the capsule/pod would surely cause anxiety with several passengers. A representation of the outside world shown within the pod/capsule using augmented windows alleviates this claustrophobic environment. At least for the closest passenger to the window, the illusion of looking out on a landscape is achieved using such augmented windows.

To allow a better coordination between an image creation artist such as a movie director of photography and the final viewer, via a receiving-side display and its corresponding image processing, a method of adding display rendering specification information to an input image signal (I) comprises determining descriptive data (D) that includes at least identification information for at least one luminance regime subset of pixels of an input image; and encoding the descriptive data (D) into an output description data signal (DDO), relatable to an output image signal (O) based upon an input image signal (I), of the descriptive data (D) in a technical format standardized to be intended for use by a receiving-side display to control its image processing for changing the color properties of its rendered images.

To allow a better coordination between an image creation artist such as a movie director of photography and the final viewer, via a receiving-side display and its corresponding image processing, a method of adding display rendering specification information to an input image signal (I) comprises determining descriptive data (D) that includes at least identification information for at least one luminance regime subset of pixels of an input image; and encoding the descriptive data (D) into an output description data signal (DDO), relatable to an output image signal (O) based upon an input image signal (I), of the descriptive data (D) in a technical format standardized to be intended for use by a receiving-side display to control its image processing for changing the color properties of its rendered images.

According to an embodiment, a source object presented in a source video is identified. Attribute information of the source object in respective frames of a sequence of source frames in the source video is identified. The attribute information represents an animation effect associated with the source object across the sequence of source frames. The attribute information is provided for use in reproducing the animation effect in a target video.