Systems and methods are described for connecting with LEO satellites while reducing emissions toward GEO satellite communications. A system to implement the instant techniques may include a system comprised of a user communications equipment and a LEO constellation. The user equipment (UE) may comprise a communications modem and an active antenna unit with a transmit and receive beamformer. In further implementations, the UE may include additional receive only beamformers. The LEO constellation can have a regenerative payload or bent pipe, and can include orbits at different altitudes. Methods as described herein may include a procedure by which the user equipment and LEO satellite work together to identify candidate serving satellites, and select the one that allows to meet the power density requirements to avoid interfering with the GEO satellites.

Systems and methods of the present disclosure may use a satellite operations center (SOC) to access an activity queue of satellite activity tasks in an activity buffer, each satellite activity task being associated with at least one satellite in a fleet. The SOC may determine mission critical variables associated with each satellite activity task based on space environment context data, satellite telemetry data, the position of each satellite, and the trajectory of each satellite. The SOC may determine, for each satellite activity task, using at least one statistical model, a prioritization tier based on the mission critical variables of each satellite activity task, and determine a satellite activity order defining an order of the satellite activity tasks based on the prioritization tier of each satellite activity task. The SOC may modify the activity buffer to order the satellite activity tasks in the activity queue according to the satellite activity order.

A satellite communications system comprises multiple satellites (e.g., a combination of LEO/MEO/GEO satellites). Multiple satellite gateways communicate over channels of the satellites with remote mobile user terminals. The mobile user terminals communicate with the satellite gateways via associated satellite terminals that interface with the satellites, or directly with the satellites. Each mobile user terminal of a first group communicates with a satellite gateway, over satellite channels, via an associated satellite terminal. Each mobile user terminal of a second group (e.g., in a remote rural area) communicates with a satellite gateway directly over satellite channels. The mobile user terminals of the first communicate with the satellite terminals locally via S-band. The mobile user terminals of the second group communicate directly over the satellite channels via Ku band or Ka Band. Each of the satellite gateways communicates over satellite channels via Ka band, Ku band, V-band or L-band.

The present disclosure relates, in part, to non-terrestrial communication systems, and in some embodiments to the integration of terrestrial and non-terrestrial communication systems. Non-terrestrial communication systems can provide a more flexible communication system with extended wireless coverage range and enhanced service quality compared to conventional communication systems.

Systems and methods are described for connecting with LEO satellites while reducing emissions toward GEO satellite communications. A system to implement the instant techniques may include a system comprised of a user communications equipment and a LEO constellation. The user equipment (UE) may comprise a communications modem and an active antenna unit with a transmit and receive beamformer. In further implementations, the UE may include additional receive only beamformers. The LEO constellation can have a regenerative payload or bent pipe, and can include orbits at different altitudes. Methods as described herein may include a procedure by which the user equipment and LEO satellite work together to identify candidate serving satellites, and select the one that allows to meet the power density requirements to avoid interfering with the GEO satellites.

A system and method for networked geofencing includes identifying restricted areas in a service region, and defining a protective zone surrounding the restricted areas. A service availability map containing the protective zones is generated and broadcast within the service region. The positions of terminals on the service availability map are detected relative to the protective zones. Terminals inside the protective zones establish communication using a first frequency range, and terminals outside of the protective zones establish communication using either the first frequency range or a second frequency range.

In some embodiments, a disclosed method involves receiving, by a source gateway, a call request from a source user terminal for establishing a call with a destination user terminal. The method further involves determining, by a source client proxy of the source gateway, a capability related to a parameter(s) of the source user terminal and a capability related to a parameter(s) of the destination user terminal. Also, the method involves sending, by the source client proxy, a call capability offer to a destination gateway based on the determined capabilities. Additionally, the method involves determining, by a destination client proxy of the destination gateway, whether the destination user terminal can support the call capability offer. Also, the method involves sending, by the destination client proxy, a call initiation message to the destination user terminal, when the destination client proxy determines that the destination user terminal can support the call capability offer.

A system is provided for reducing latency data collection from space-based sensor satellites. A mobile vehicle platform, configured to travel around the Earth, includes a sensor module and a relay satellite terminal. The sensor module monitors certain conditions, circumstances, environments and/or situations occurring on or around, or associated with, the Earth, and generates sensor data resulting from the monitoring. The relay satellite terminal executes data communications with a first of a plurality of satellites while the mobile vehicle platform is in a first area within a communications range of the first satellite, and, upon moving to a second area within a communications range of a second of the plurality of satellites, the relay satellite terminal switches the data communications to the second satellite. The data communications relay the sensor data, via the satellites, to a central processing facility for aggregation, processing, analysis and/or dissemination of the data.

Methods and systems for managing relays in LTE based communication networks. Embodiments herein use of a packet handler node and an additional radio interface in the UE, enabling the creation of an overlay network on top of an existing LTE network. The overlay network helps in the transfer of data between the UE and the AS even when the UE is not directly connected to the LTE network by encapsulating the data from the out-of-coverage UE within the IP packet of at least one nearby relay UE connected to the LTE network and is then forwarded to the LTE core network. The out-of-coverage UE uses the additional radio interface to send packets to the relay UE.

A method of operating a communications device for transmitting signals to and/or receiving signals from a non-terrestrial network (NTN) apparatus of a wireless communications network. The communications device acquires information for synchronising a transmission with the NTN apparatus. The communications device estimates a time remaining until an expiry time at which the information for synchronising the transmission with the apparatus will become invalid. The communications device receives, from the NTN apparatus, a biasing signal providing an indication to the communications device to bias an estimate of a time required to communicate the transmission with the NTN apparatus. The communications device determines, based at least in part on the indication provided by the biasing signal, the biased estimate of the time required to communicate the transmission with the NTN apparatus.