A system for transmitting camera data may include (i) identifying at least two streams of video data that are each produced by a different video source, (ii) receiving a set of at least two frames of video data that includes exactly one frame from each of the at least two streams of video data, (iii) placing, within an image, the set of at least two frames of video data received from the at least two streams of video data, and (iv) transmitting the image that includes the set of at least two frames of video data received from the at least two streams of video data via a single transmission channel. Various other apparatuses, systems, and methods, are also disclosed.

An apparatus includes a first video capture device, a second video capture device and a circuit. The first video capture device may be configured to capture a first plurality of video frames of a first field of view. The second video capture device may be configured to capture a second plurality of video frames of a second field of view. The circuit may be configured to generate a first video stream in response to the first video frames, generate a second video stream in response to the second video frames and wirelessly communicate the first video stream and the second video stream to a device. The first field of view may capture an area in front of the apparatus. The second field of view may capture an area under and behind the apparatus. The second field of view may comprise a blind spot of the first field of view.

A method, system, and computer program product for transferring image data taken by an on-vehicle camera. The image data and nearby-vehicle information on a vehicle are received, where the image data and the nearby-vehicle information are successively transferred from each of a plurality of vehicles capable of making a communication with each other. Furthermore, information on a line of vehicles is generated based on the nearby-vehicle information. The image data is then associated with the information on the line of vehicles. Display data may then be generated using the image data. Furthermore, the display data may be presented on a display device in the vehicle.

Approaches for dynamically allocating compute capacity for processing a video stream. Video complexity information for two or more digital video streams actively being processed by one or more video encoders is determined at periodic intervals. Video complexity information describes the complexity of digital video carried by the digital video streams across a bounded number of consecutive digital frames which includes digital frames not yet processed by the one or more video encoders. A determination is made as to whether the compute capacity allocated for processing a particular digital video stream should be adjusted in some manner based on the determined video complexity information. The amount of compute capacity allocated for processing the particular digital video stream may be dynamically adjusted in response to maximizing a measure of optimal video quality calculated for the two or more digital video streams using, at least in part, the determined video complexity information.

Methods and apparatus provide for: receiving an embedded image having different information embedded in an unused area of a rectangular image format for transmitting a primary image obtained by correcting beforehand an original image in a manner canceling out the distortion thereof that appears when viewed through lenses of a head-mounted display; outputting directly to a panel of the head-mounted display the embedded image received by the receiving section; and recomposing the different information by extracting the data thereof from the unused area for the embedded image.

An image display device including a display; a first input configured to receive a first image signal input from a first external device connected to the image display device; a second input configured to receive a second image signal input from a second external device connected to the image display device; and a controller coupled with the display, the first input and the second input. The controller is further configured to display, on the display, a plurality of external device icons including a first external device icon and a second external device icon, wherein a first default image identifying the first input is displayed on the first external device icon and a second default image identifying the second input is displayed on the second external device icon, change the first default image to a first image based on the first image signal received from the first external device in response to the first external device icon being selected if the first external device is connected to the image display device, and change the first image back to the first default image in response to the second external device icon being selected, wherein the first image is displayed at a position corresponding to an area where the first external device icon is displayed.

Embodiments of the present invention are directed to a social entertainment platform that supports live social video streaming and messaging. One common use for this social entertainment platform is to allow audience members to watch and interact with a person playing an electronic game. The social entertainment platform allows a streamer to stream live (in substantially real-time) on a network(s), such as the Internet, for a live audience to view and to respond to the live entertainment. The social entertainment platform includes several unique areas, including a real-time broadcasting component, a real-time messaging component, and an integrated user interface (UI) component, that make the social entertainment platform advantageous to use over traditional platforms.

[Problem] To make a device compact and inexpensive by omitting a frame buffer. [Solution] First packet data PD1 that is sequentially received from a first camera C1 and second packet data PD2 that is sequentially received from a second camera C2 are alternately and sequentially transmitted to an external device 2 before data for one screen is accumulated. Therefore, a frame buffer for saving the data for one screen is not necessary, and a device can be made correspondingly more compact and less expensive.

A transmission apparatus includes a video obtainer configured to obtain a video signal, a first converter configured to convert the video signal into an electrical signal complying with a high definition multimedia interface (HDMI (registered trademark)) standard, a second converter configured to convert the video signal into an optical signal, and a signal processor configured to perform at least one of the conversion using the first converter and the conversion using the second converter with respect to the obtained video signal.

An apparatus includes a first video capture device, a second video capture device and a circuit. The first video capture device may be configured to capture a first plurality of video frames of a first field of view. The second video capture device may be configured to capture a second plurality of video frames of a second field of view. The circuit may be configured to generate a first video stream in response to the first video frames, generate a second video stream in response to the second video frames and wirelessly communicate the first video stream and the second video stream to a device. The first field of view may capture an area in front of the apparatus. The second field of view may capture an area under and behind the apparatus. The second field of view may comprise a blind spot of the first field of view.