There is disclosed a streaming technique in which a distributed playback, DP, master device receives a media stream from a content provider and transmits the media stream to a plurality of DP client devices. The DP master device may follow different policies. In case one DP client device has not a level of security sufficient for a particular quality, one policy provides that the stream is degraded, while another policy provides that the stream is to be transmitted by a content provider at a reduced quality.

A device includes a touch-screen display and a lens on a same side of the device as the touch-screen display. The device concurrently displays a live preview of content in a field of view of the lens and a capture affordance for capturing media corresponding to the field of view of the lens. While concurrently displaying the live preview and the capture affordance, the device detects an input corresponding to selection of the capture affordance displayed on the touch-screen display that is on the same side of the device as the lens. In response to detecting the input corresponding to selection of the capture affordance displayed on the touch-screen display that is on the same side of the device as the lens, the device captures media corresponding to the field of view of the lens that is on the same side of the device as the touch-screen display.

Provided herein are system, apparatus, device, method and/or computer program product embodiments, and/or combinations and sub-combinations thereof, for streaming a video chat from a mobile device on a display device. In a given embodiment, a first mobile device and second video device can communicate audio and video data to one another, via a video chat. The incoming audio and video data for the first mobile device can be streamed to and output by an external display device. The streaming request is generated in response to the first mobile device coupling with a rotating base, controlled by the first mobile device.

An example operating method of a display device for displaying a multi-view screen including a plurality of partial screens includes respectively outputting a plurality of pieces of content, which are individually decoded, through the plurality of partial screens, identifying at least one of the plurality of pieces of content, based on a video call request, and outputting a video call screen through at least one partial screen corresponding to the identified at least one content from among the plurality of partial screens.

The present invention provides a signal processing device including a receiver, a signal processor and a transmitter. The receiver is configured to receive a first video signal. The signal processor is coupled to the receiver and configured to support a plurality of scene modes, select a current scene mode form the plurality of scene modes according to a user input, and operate in the current scene mode to process the first video signal to generate a second video signal. The transmitter is configured to output the second video signal.

An artificial intelligence (AI) decoding apparatus includes a memory storing one or more instructions, and a processor configured to execute the stored one or more instructions, to obtain image data corresponding to a first image that is encoded, obtain a second image corresponding to the first image by decoding the obtained image data, determine whether to perform AI up-scaling of the obtained second image, based on the AI up-scaling of the obtained second image being determined to be performed, obtain a third image by performing the AI up-scaling of the obtained second image through an up-scaling deep neural network (DNN), and output the obtained third image, and based on the AI up-scaling of the obtained second image being determined to be not performed, output the obtained second image.

A source device for transmitting content to a sink device is provided. The source device may include an interface configured to perform high-bandwidth digital content protection (HDCP) authentication with the sink device, and a controller configured to determine an HDCP version supported by the sink device, convert the content so as to be encrypted in the HDCP version supported by the sink device in response to a determination that another HDCP version applied to the content is not supported by the sink device, encrypt the converted content in the HDCP version supported by the sink device, and control the interface to transmit the content to the sink device.

A method disclosed herein provides for receiving, at a user device, a media stream including frames of a first resolution generated by a graphics-rendering application and utilizing one or more weight matrices pre-trained in association with the graphics-rendering application to locally upscale each received frame of the media stream at the user device to a second resolution greater than the first resolution. Local upscaling of the media stream may be performed “on the fly,” such as with respect to individual content streams (e.g., a game) or segments of content streams (e.g., a scene within a game).

Video and corresponding metadata is accessed. Events of interest within the video are identified based on the corresponding metadata, and best scenes are identified based on the identified events of interest. Events of interest can be tagged within the video based on, for instance, user input, audio signals, motion vectors, and metadata corresponding to the video. A camera system can process video data based on the events of interest tagged within the video before outputting the video data. For instance, video scenes associated with tagged events of interest can be combined to form a video highlight clip. Likewise, portions of video tagged with events of interest can be encoded or stored at a higher resolution or frame rate than other portions of the video.

Embodiments of this application relate to the field of terminal technologies, and describe a method for displaying a dynamic image and a terminal, which resolve a problem that power consumption of a terminal caused by an existing method in which three-dimensional real-time rendering is used is relatively high. The method may be applied to a terminal, and can includes obtaining, from a video file based on a preset factor, a plurality of pieces of image frame data in a one-to-one correspondence to a plurality of image frames. The method may also include decoding the plurality of pieces of image frame data, to obtain the plurality of image frames. Furthermore, the method can include successively displaying the plurality of image frames obtained through the decoding, to present the dynamic image.