An example method, performed by an edge data network, of transmitting video content includes: obtaining first bearing information from an electronic device connected to the edge data network; determining second predicted bearing information based on the first bearing information; determining a second predicted partial image corresponding to the second predicted bearing information; transmitting, to the electronic device, a second predicted frame generated by encoding the second predicted partial image; obtaining, from the electronic device, second bearing information corresponding to a second partial image; comparing the second predicted bearing information to the obtained second bearing information; generating, based on a result of the comparing, a compensation frame using at least two of a first partial image corresponding to the first bearing information, the second predicted partial image, or the second partial image corresponding to the second bearing information; and transmitting the generated compensation frame to the electronic device based on the result of the comparing.

An example method, performed by an edge data network, of transmitting video content includes: obtaining first bearing information from an electronic device connected to the edge data network; determining second predicted bearing information based on the first bearing information; determining a second predicted partial image corresponding to the second predicted bearing information; transmitting, to the electronic device, a second predicted frame generated by encoding the second predicted partial image; obtaining, from the electronic device, second bearing information corresponding to a second partial image; comparing the second predicted bearing information to the obtained second bearing information; generating, based on a result of the comparing, a compensation frame using at least two of a first partial image corresponding to the first bearing information, the second predicted partial image, or the second partial image corresponding to the second bearing information; and transmitting the generated compensation frame to the electronic device based on the result of the comparing.

A computer-implemented method is provided. The method includes executing a video game on a server unit and said server unit producing uncompressed interactive video. The method includes processing the uncompressed interactive video at a compression unit associated with the server unit. The compression unit outputting compressed interactive video, and the server unit and the compression unit being located at a data center. The method includes streaming the compressed interactive video over a packetized network from the data center to one or more client devices associated with one or more users. Each client device is located geographically remote to the data center, and the server is configured to receive input to drive gameplay of the video game by said one or more client devices. The compressed interactive video is configured for decompression and presentation at said one or more client devices. The method includes receiving, by the server, updates from said one or more clients devices regarding a quality of said uncompressed interactive video that is received from said streaming. The method includes adjusting automatically, by the compression unit, a rate of compression provided to one or more of said client devices based on said updates received regarding the quality of said uncompressed interactive video for the video game.

A computer-implemented method is provided. The method includes executing a video game on a server unit and said server unit producing uncompressed interactive video. The method includes processing the uncompressed interactive video at a compression unit associated with the server unit. The compression unit outputting compressed interactive video, and the server unit and the compression unit being located at a data center. The method includes streaming the compressed interactive video over a packetized network from the data center to one or more client devices associated with one or more users. Each client device is located geographically remote to the data center, and the server is configured to receive input to drive gameplay of the video game by said one or more client devices. The compressed interactive video is configured for decompression and presentation at said one or more client devices. The method includes receiving, by the server, updates from said one or more clients devices regarding a quality of said uncompressed interactive video that is received from said streaming. The method includes adjusting automatically, by the compression unit, a rate of compression provided to one or more of said client devices based on said updates received regarding the quality of said uncompressed interactive video for the video game.

This application pertains to gift-giving and video-dropping methods and systems. A gift drop or a video drop is facilitated using a mobile smart device and an interactive map. The system includes a gift or video drop database stored in a remote gift drop computer server. The system includes a gift or video drop logic section operable on a smart mobile device or a computer. The gift or video drop logic section includes an interactive gift or video drop map. The gift or video drop logic section presents the interactive gift or video drop map to a user, and facilitates the dropping of a symbolic gift item or a video onto the interactive map. The gift or video drop logic section determines whether the user is within certain predefined geographic boundaries, and either makes visible or gives a symbolic gift item to the user based on their location, or plays the video.

This application pertains to gift-giving and video-dropping methods and systems. A gift drop or a video drop is facilitated using a mobile smart device and an interactive map. The system includes a gift or video drop database stored in a remote gift drop computer server. The system includes a gift or video drop logic section operable on a smart mobile device or a computer. The gift or video drop logic section includes an interactive gift or video drop map. The gift or video drop logic section presents the interactive gift or video drop map to a user, and facilitates the dropping of a symbolic gift item or a video onto the interactive map. The gift or video drop logic section determines whether the user is within certain predefined geographic boundaries, and either makes visible or gives a symbolic gift item to the user based on their location, or plays the video.

A broadcast reception device includes: a program recording execution unit that stores, into a recording-content storage area, program identification information for identifying a broadcast program, and storage-destination information for specifying a server device storing the broadcast program; a reception function execution unit that transmits the program identification information and the program storage-destination information to the server device specified from the program storage-destination information; and an output unit that outputs sound information and image information on the broadcast program transmitted from the server device.

In one embodiment, a system includes a CATV node, a first device, and at least one micro distribution system. The CATV node transmits CATV RF signals to the first device, which converts the RF signals to optical signals. Each micro distribution system includes a micro node receiving the optical signals from the first device and converting the optical signals to RF signals. Each micro distribution system further includes at least two strings of taps independently coupled to the micro node and receiving the RF signals from the micro node. Each string of taps is terminated at an end by a low pass filter (LPF). For each string of taps, the received RF signals are passed from the micro node along the taps and blocked by the LPF, while a powering signal is passed along the taps and through the LPF.

In one embodiment, a system includes a CATV node, a first device, and at least one micro distribution system. The CATV node transmits CATV RF signals to the first device, which converts the RF signals to optical signals. Each micro distribution system includes a micro node receiving the optical signals from the first device and converting the optical signals to RF signals. Each micro distribution system further includes at least two strings of taps independently coupled to the micro node and receiving the RF signals from the micro node. Each string of taps is terminated at an end by a low pass filter (LPF). For each string of taps, the received RF signals are passed from the micro node along the taps and blocked by the LPF, while a powering signal is passed along the taps and through the LPF.

In one embodiment, a system includes a CATV node, a first device, and at least one micro distribution system. The CATV node transmits CATV RF signals to the first device, which converts the RF signals to optical signals. Each micro distribution system includes a micro node receiving the optical signals from the first device and converting the optical signals to RF signals. Each micro distribution system further includes at least two strings of taps independently coupled to the micro node and receiving the RF signals from the micro node. Each string of taps is terminated at an end by a low pass filter (LPF). For each string of taps, the received RF signals are passed from the micro node along the taps and blocked by the LPF, while a powering signal is passed along the taps and through the LPF.