The invention provides a method and an architecture for deploying non-terrestrial cellular network base stations, so as to enable cellular network coverage in remote areas, where no fixed infrastructure is available. The proposed methods allow for efficient power management at the terminal devices that need to synchronize to the airborne or spaceborne cellular base stations. This is particularly important for IoT devices, which have inherently limited power are computing resources.

Methods, systems, and devices for wireless communication are described. A communication device, such as a user equipment (UE) may transmit, to a base station of a non-terrestrial network, a random access request message associated with a random access procedure using a transport block size (TBS) and a power control specified for the random access request message (e.g., a payload of the random access request message) for the random access procedure. The random access request message including a random access preamble and a random access payload carrying a buffer status report (BSR) or uplink data, or both. The UE may then monitor a response window based at least in part on transmitting the random access request message. The UE may receive, from the base station of the non-terrestrial network, a response message of the random access procedure during the response window.

A method and apparatus for supporting communication in a network, such as a satellite mesh network. Network nodes maintain network status awareness for a limited region through flooding notifications. Network nodes may route packets by addressing them to other nodes within the limited region. Notifications of events are propagated not only to nearby nodes whose region includes the event location, but also a certain distance beyond such nearby nodes. This assists in propagating the notifications back toward the nearby nodes, in order to increase the likelihood that each network node maintains required awareness even when network failures occur. A node in receipt of an event notification will adjust its awareness when the node is within a first distance of the event. If the node is within a second, greater distance of the event, the node will refrain from adjusting its awareness but will forward the notification to further nodes.

Disclosed are an apparatus and method in a wireless communication system and a computer readable storage medium. The apparatus comprises a processing circuit, configured to: obtain at least height information of each user equipment among one or more user equipments; and for each user equipment, allocate resources to the user equipment on the basis of at least the height information of the user equipment and one or more height thresholds for the user equipment. According to at least one aspect of embodiments of the present disclosure, resources are allocated on the basis of a height threshold, so that time-frequency resource allocation in an unmanned aerial vehicle communication scenario may be optimized, resource utilization efficiency may be improved, and interference may be reduced.

A wireless device, UE, in a communication network receives satellite positioning information and a list of a plurality of different types of measurements to perform to find a public land mobile network, PLMN, to select. The UE performs the plurality of different types of measurements on a frequency associated with a found PLMN to generate a plurality of measurement results. The UE determines, based on the plurality of measurements results, whether a high-quality indication should be provided to a non-access stratum, NAS. Responsive to determining that the high-quality indication should be provided, the UE provides the high quality indication and an identification of the found PLMN to the NAS.

Methods for selecting and configuring a random access channel, an access device and a network device are provided. The method includes: obtaining parameter information and time-frequency resource allocation information corresponding to at least two types of random access channels, the parameter information including a subcarrier spacing and a preamble sequence, a random access channel bandwidth obtained in accordance with the subcarrier spacing and a length of the preamble sequence being smaller than or equal to a maximum transmission bandwidth of a satellite access device, the subcarrier spacing including a reference value of a maximum frequency offset to be resisted by a satellite system; selecting target parameter information from the parameter information in accordance with a capability and an operating scenario of the access device and a frequency offset proportion of each random access channel; and selecting a random access channel in accordance with the target parameter information, and transmitting a random access signal in accordance with the time-frequency resource allocation information.

A satellite receiver includes: N reception antenna elements; N demultiplexing units; a correlation detection unit configured to perform correlation processing on each of reception signals demultiplexed by the N demultiplexing units with a reception antenna element that receives the highest power being set as a reference element so as to calculate a relative phase difference, and calculate an excitation coefficient for cancelling a phase difference between the N reception antenna elements for each of sub-channels based on the calculated relative phase difference; N phase compensation units configured to multiply the reception signals demultiplexed by the N demultiplexing units, respectively, by the excitation coefficient for each of the sub-channels; and a combiner configured to combine multiplication results from the N phase compensation units for each of the sub-channels to generate output signals.

Methods, systems, and devices for wireless communication are described. A communication device, such as a user equipment (UE) may transmit, to a base station of a non-terrestrial network, a random access request message associated with a random access procedure using a transport block size (TBS) and a power control specified for the random access request message (e.g., a payload of the random access request message) for the random access procedure. The random access request message including a random access preamble and a random access payload carrying a buffer status report (BSR) or uplink data, or both. The UE may then monitor a response window based at least in part on transmitting the random access request message. The UE may receive, from the base station of the non-terrestrial network, a response message of the random access procedure during the response window.

A satellite provides communication between user terminals (UTs) and ground stations that connect to other networks, such as the Internet. Because the satellite is within range of many UTs at any given time, many UTs are in contention to use an uplink to send data to the satellite. Each satellite manages uplink contention by maintaining state data representative of the uplink resources allocated for use. As satellites move, handovers take place, transferring communication services from a first satellite to a second satellite. Before a handover, a first satellite sends state data to a UT. The second satellite is also informed about the UT. After the handover, the second satellite provides the UT with priority access to the uplink to send the state data to the second satellite. The second satellite uses the state data to resume management of the uplink, eliminating the need for time consuming link setup.

A method and apparatus for supporting communication in a network, such as a satellite mesh network. Network nodes maintain network status awareness for a limited region through flooding notifications. Network nodes may route packets by addressing them to other nodes within the limited region. Notifications of events are propagated not only to nearby nodes whose region includes the event location, but also a certain distance beyond such nearby nodes. This assists in propagating the notifications back toward the nearby nodes, in order to increase the likelihood that each network node maintains required awareness even when network failures occur. A node in receipt of an event notification will adjust its awareness when the node is within a first distance of the event. If the node is within a second, greater distance of the event, the node will refrain from adjusting its awareness but will forward the notification to further nodes.