Provided are a synchronisation method, a terminal device, a network device and a storage medium, capable of ensuring synchronisation between a terminal and a satellite system via D2D means. In the method, a network device determines that a first terminal cannot synchronise with a satellite system; the network device instructs a second terminal to send a satellite system-based synchronisation signal, used for the first terminal to synchronise with the satellite system via the synchronisation signal. In a possible implementation, the method may include that: the network equipment receives a first message sent by the first terminal, the first message indicating that the first terminal is not able to be synchronized with the satellite system and the first message including information configured to acquire the present position of the first terminal.

Connection control circuitry is provided for a User Equipment (UE) configurable to offload communication of packet data from a cellular radio-access network comprising a Trusted Wireless Local Access Network (TWLAN) and a Trusted Wireless Access Gateway (TWAG) with IP Address preservation. The connection control circuitry has a connection requesting module configured to send a distinguishable-connection establishment message to the TWAG, requesting setup of a TWAG-routed data connection comprising at least one of a Packet Data Network (PDN) connection and a Non-Seamless Wireless Offload (NSWO) connection. A unique virtual gateway interface address is used to identify a point-to-point link between the UE and the TWAG. This allows the TWAG to distinguish between multiple substantially simultaneous point-to-point links which support multiple substantially simultaneous packet data connections. Other embodiments may be described and claimed.

A method of communicating between a rotary wing platform and a ground terminal via a satellite. The method comprises, at the rotary wing platform, receiving a forward link signal transmitted by the satellite; on the basis of the received forward link signal, estimating at least one obstruction characteristic associated with obstruction of a signal transmission path between the rotary wing platform and the satellite by one or more blades of the rotary wing platform; determining a plurality of time periods during which the at least one obstruction characteristic indicates that the signal transmission path will not be obstructed by the one or more blades of the rotary wing platform; and transmitting to the satellite a bursted carrier return link signal comprising a plurality of bursts, wherein each burst in the plurality of bursts is transmitted during one of the determined time periods.

A channel latency determining method, a positioning method, and device, the method including obtaining, by a communications device, device location information of a calibration user equipment (UE), calculating a propagation delay according to the device location information and prestored location information of an antenna, where the propagation delay is a time between transmitting a radio signal by the calibration UE and receiving the radio signal by the antenna, calculating a time of arrival according to the radio signal transmitted by the calibration UE to the antenna, where the time of arrival is a time obtained through calculation according to a time of arrival (TOA) estimation algorithm, and determining a channel latency according to the propagation delay and the time of arrival, where the channel latency is positively correlated with the time of arrival and is negatively correlated with the propagation delay.

Some embodiments provide a method for channel estimation in a wireless device. According to the method, the wireless device obtains (1010) an indication that a set of antenna ports, or antenna port types, share at least one channel property. The wireless device then estimates (1020) one or more of the shared channel properties based at least on a first reference signal received from a first antenna port included in the set, or having a type corresponding to one of the types in the set. Furthermore, the wireless device performs (1030) channel estimation based on a second reference signal received from a second antenna port included in the set, or having a type corresponding to one of the types in the set, wherein the channel estimation is performed using at least the estimated channel properties.

Embodiments of the present disclosure provide an information transmission method, including: determining, by a user equipment (UE), first speed information of the UE; determining, by the UE, a transmission manner of control information based on the first speed information; and sending, by the UE, the control information in the transmission manner over a first link. In the embodiments of the present disclosure, the UE may determine the transmission manner of the control information based on the first speed information. When the UE is high speed UE, an appropriate transmission manner can be selected for the high speed UE, thereby meeting a transmission requirement of the high speed UE and ensuring a transmission success rate.

An apparatus for use in a RAN network node includes processing circuitry coupled to a memory. To configure the RAN network node for positioning measurement reporting in a wireless network, the processing circuitry is to decode a measurement request message from a location management function (LMF) node of the wireless network. The processing circuitry also encodes a measurement response message for transmission to the LMF node based on the measurement request message.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may use a measurement procedure for beam detection within an existing cell. The UE perform a search procedure for a first synchronization signal block (SSB) to detect a first beam of a base station. The UE may determine a first timing offset for the first SSB based on the search procedure. The UE may estimate a second timing offset for a second SSB from the base station based on the first timing offset. The UE may perform a measurement procedure for the second SSB to detect a second beam of the base station based on the second timing offset. The UE may prune fake beams based on synchronization signals used for the measurement procedure.

A method of detecting a synchronization switching pulse using a power detector in a time division duplexing (TDD) system includes receiving an input signal, detecting a power level associated with the input signal using a digital power meter, and determining a configuration associated with the input signal. The method also includes determining that a pulse width associated with the input signal is greater than a threshold, determining an offset associated with a special subframe configuration, and generating an estimated sync pulse. The method further includes forming a regenerated sync pulse, determining an error between the estimated sync pulse and the regenerated sync pulse, determining that the error is less than a threshold, and providing a lock detect.

In an embodiment, a UE establishes, with a peer sidelink UE, at least one sidelink communications link that each comprises one or more hops. The UE determines estimates a propagation delay between the UE and the peer sidelink UE based in part upon a relationship between a propagation time, between the UE and the peer sidelink UE, and Reference Signal Received Power (RSRP) irrespective of whether the UE remains synchronized with respect to the network clock.