Methods and systems including computer programs encoded on computer storage media, for training and deploying machine-learned communication over RF channels. One of the methods includes: determining first information; generating a first RF signal by processing the first information using an encoder machine-learning network of the first transceiver; transmitting the first RF signal from the first transceiver to a communications satellite or ground station through a first communication channel; receiving, from the communications satellite or ground station through a second communication channel, a second RF signal at a second transceiver; generating second information as a reconstruction of the first information by processing the second RF signal using a decoder machine-learning network of the second transceiver; calculating a measure of distance between the second information and the first information; and updating at least one of the encoder machine-learning network of the first transceiver or the decoder machine-learning network of the second transceiver.

Various arrangements for facilitating smart television content receivers in a local network are provided. A primary television receiver executing a first operating system can receive audio data including human voice from a voice enabled remote control. The primary television receiver can transmit the audio data to a secondary television receiver executing a second operating system and that includes a voice command component. The secondary television receiver can convert the audio data into voice command data and transmit the voice command data to the primary television receiver. The primary television receiver can transmit the voice command data to a voice processing server via the Internet and receive, in response, a command generated based on the voice command data. The primary television receiver can transmit the command to the secondary television receiver. The voice command component can then control an operation of the secondary television receiver based on the command.

Methods, methods, and non-transitory, machine-readable media to facilitate streaming in a local network with a client-server architecture are disclosed. A primary media device may be configured to: operate as a server in a local network, receive first audio/video (A/V) content via an Internet connection, and receive second A/V content via a satellite network connection. Each secondary media device of a set of one or more secondary media devices may be configured to: operate as a client with respect to the primary media device in the local network, receive the first A/V content from the primary media device, receive the second A/V content from the primary media device, and provide the first A/V content and the second A/V content to at least one television of a set of one or more televisions.

Systems, methods, and non-transitory, machine-readable media to facilitate streaming in a local network with a client-server architecture are disclosed. A configuration tool may configure a primary media device to perform operations with respect to a local network. The configuration tool may be adapted to communicatively couple with the primary media device via at least one interface of the one or more interfaces to configure the primary media device to perform the operations with respect to the local network. The primary media device may be configured with the configuration tool to operate as a server in the local network, receive first audio/video (A/V) content via an Internet connection and/or a satellite network connection, and receive second A/V content via the Internet connection and/or the satellite network connection.

Various arrangements for facilitating smart television content receivers are provided. A primary television receiver (PTR) having a first operating system may be configured to receive digital content from a remote content provider and distribute the content to one or more devices in response to a request for the content. A secondary television receiver (STR) configured to be in communication with a PTR and having a second operating system may be configured to receive the digital content from the PTR and provide the content to a display for presentation. The STR may include a first software stack including first processes and a first inter-process communication (IPC) mechanism, and a second software stack including second processes and a second IPC mechanism. The first processes may use the first IPC to communicate with the second processes. The second processes may use the second IPC to communicate with others of the second processes.

Disclosed herein is a receiver that generates a video signal. A first video is assigned to a first display layer of a plurality of display layers. A first trigger signal causes a first application to assign a first user interface to a second display layer, which is positioned over the first display layer. A second trigger signal causes a second application to assign a second user interface to a third display layer, which is positioned over the second display layer. The second trigger signal causes a reduction in a size of the first video, and a first portion of the third display layer and a second portion of the second display layer to be made transparent. The reduced size of the first video is positioned beneath the first portion. A combination of the first display layer, the second display layer, and the third display layer generates the video signal.

Various arrangements for spectrum sharing among a terrestrial network and a non-terrestrial network are presented herein. A first bandwidth part having a first frequency range for may be assigned use for communication between one or more UE of a plurality of UE and a terrestrial cellular network when a high signal strength is present. A second bandwidth part having a second frequency range may be assigned for use for communication between one or more UE of the plurality of UE and the terrestrial cellular network when a low signal strength is present. A third bandwidth part having a third frequency range can be assigned for use for communication between one or more UE of the plurality of UE and a non-terrestrial network. The third bandwidth part can overlap with the first bandwidth part but not the second bandwidth part.

A data broadcast method includes obtaining, by a satellite base station, a plurality of pieces of data that are to be broadcast. The plurality of pieces of data are a same type of data including compensation values of Doppler frequency shifts, change rates of Doppler frequency shifts, transmission delays, change rates of transmission delays, timing advances TAs, change rates of TAs, or angles of a plurality of beams that respectively correspond to a plurality of beams generated by the satellite base station. The satellite base station determines reference data and a difference between each piece of data in the plurality of pieces of data and the reference data. The satellite base station sends first indication information and a plurality of pieces of second indication information to a terminal device. The first indication information indicates the reference data.

The present disclosure relates to a system for providing an anonymous and obfuscated communication over a virtual, modular and distributed satellite communication network.

The described features generally relate to receiving one or more positioning signals at a satellite terminal during installation of the satellite terminal at a customer premises, and providing position-based access to a satellite communications system based on a satellite terminal installation position determined from the received positioning signals. The determined installation position of the satellite terminal may then be employed for various network access techniques, such as providing access to the satellite communications system, providing position-based content, or restricting content via the satellite communications system based on the determined installation position. In some examples the determined installation position of the satellite terminal may be used to approximate a propagation delay between the satellite terminal and various devices of the satellite communications system, such as a serving satellite and/or a serving gateway, to improve device synchronization and radio frequency spectrum resource utilization.