Systems and methods for communicating with one or more satellites to acquire information related to a region on a map that is displayed on a mobile device. A mobile device includes: a communication device for directly communicating data with a satellite; a display for displaying a graphic user interface (GUI) that shows an image of a map; one or more processors; and a non-transitory computer-readable medium comprising one or more sequences of instructions which, when executed by the one or more processors, causes steps to be performed comprising: responsive to a touch on the GUI, sending a request signal for information related to a region on the map directly to the satellite via the communication device; receiving the information related to the region on the map directly from a satellite; and displaying the information on the display.

The disclosure provides for a system that includes a network controller. The network controller is configured to receive information from nodes of a network, where nodes include one node that is in motion relative to another node. The network controller is also configured to generate a table representing nodes, available storage at each node, and possible links in the network over a period of time based on the information, and determine a series of topologies of the network based on the table. Based on received client data including a data amount, the network controller is configured to determine flows for the topology. The network controller then is configured to generate a schedule of network configurations based on the flows, and send instructions to the nodes of the network for implementing the network configurations and transmitting client data.

The present invention relates to a method for a logon procedure in a satellite communication system comprising at least one terminal, a satellite and either a gateway proxy on-board the satellite or a gateway. The method comprises transmitting a logon burst signal from a terminal of the satellite communication system to the gateway proxy on-board the satellite or the gateway, whereby the logon burst signal comprises one or more transmit parameter fields, each transmit parameter field corresponding to a signal transmit time or a signal transmit level or a signal transmit frequency of the logon burst signal in the terminal.

A system for centralized management of access subnetwork selections is disclosed. The system comprises an Internet protocol-based communications management (ICM) client located on an onboard server of each of one or more vehicles, and an ICM server located at a ground center. The ICM server is in operative communication with the ICM client on each of the one or more vehicles. The ICM client on each of the one or more vehicles is operative to communicate with the ICM server through one or more subnetworks, which are in operative communication with a ground network. The ground network communicates with the ICM server.

Devices, methods, and systems for uplink synchronization in time division multiple access (TDMA) satellite network. In one embodiment, an earth-based satellite terminal is configured to communicate with a satellite hub through a satellite using the TDMA communication protocol. The earth-based satellite terminal is configured to determine its own location, a location of the satellite, estimate a distance between the location of the terminal and the location of the satellite, determine a Coarse Timing Advance based on the distance that is estimated, and transmit data to the satellite based on the Coarse Timing Advance and the TDMA communication protocol. The Coarse Timing Advance may allow uplink TDMA communication without a preamble transmission on a random access channel, the preamble transmission being required in many conventional systems.

This disclosure provides systems, methods and apparatus, including computer programs encoded on computer storage media, for managing beam configurations and parameters for non-terrestrial networks. In some implementations, a UE may detect a synchronization signal block (SSB) transmitted by a satellite via a first beam. Aspects of the present disclosure recognize that each beam may be identified by a unique SSB index based at least in part on a time or frequency on which the SSB is received. Thus, the SSB may be identified based on a frequency-domain SSB index or a time-domain SSB index. The UE may further determine one or more wireless communication parameters associated with the first beam. The UE may generate a mapping between the SSB and the wireless communication parameters associated with the first beam, and thereafter communicate with the satellite using the mapping.

Systems and methods for aligning timing of an inroute transmission of a terminal with a gateway are disclosed. A system may include a processor and a memory storing instructions, which when executed by the processor, may cause the processor to perform a random estimation of location pertaining to a time-division multiple access (TDMA) frame boundary of a gateway. Based on an asynchronous scrambled coded multiple access (ASCMA) technique, the system may transmit ASCMA group burst packets including precise timing feedback request for the gateway. The system may receive a feedback from the gateway, in response to the precise timing feedback request. The processor may determine an adjustment for aligning timing of an inroute transmission of the terminal with respect to the TDMA frame boundary of the gateway. The system may apply the adjustment to synchronize the timing of the inroute transmission of the terminal with the gateway.

Systems and methods for communicating with one or more satellites to acquire information related to a region on a map that is displayed on a mobile device. A mobile device includes: a communication device for directly communicating data with a satellite; a display for displaying a graphic user interface (GUI) that shows an image of a map; one or more processors; and a non-transitory computer-readable medium comprising one or more sequences of instructions which, when executed by the one or more processors, causes steps to be performed comprising: responsive to a touch on the GUI, sending a request signal for information related to a region on the map directly to the satellite via the communication device; receiving the information related to the region on the map directly from a satellite; and displaying the information on the display.

The method for file transmission from a spacecraft to ground via a Free Space Optical channel comprises the use of the Consultative Committee for Space Data Systems (CCSDS) standard with assigning a File ID in the Secondary Header and dividing the transmission of the file into several fractions. The type of fraction, namely Start Transfer Frame, Intermediate Transfer Frame, or End Transfer Frame is identified in the Secondary Header. Also, the File ID, File length, and Name of the file is included in the Secondary Header of the Start Transfer Frame while information about the File ID is included also in the other two types Transfer Frames.

A satellite communication system communicates via a communication satellite using one of a plurality of portable station devices as a master station device and another portable station device as a slave station device. The master station device transmits a first control signal for the slave station device to establish synchronization. The master station device determines that the slave station device is in a communicable state by a second control signal received from the slave station device that has received the first control signal and established synchronization. The master station device selects one of at least one slave station devices in a communicable state and transmits a third control signal for instructing start of transmission of a communication signal to the selected slave station device and the subject device. Due to this, it is possible to connect a channel between portable station devices without the intervention of a control station device or a regulation station device.