A system and method for providing wireless data communication between a wireless communication system in an aircraft and a stationary communication server outside the aircraft are disclosed. The wireless communication system includes a plurality of antennas, and a router in the aircraft configured to transmit and receive wireless data communication to and from a stationary communication server outside the aircraft through at least one ground base station via at least one of the plurality of antennas. The plurality of antennas includes at least one omnidirectional antenna and at least one directional antenna. The router includes a control unit configured to restrict the wireless data communication to solely occur through the at least one directional antenna the when the current altitude of the aircraft is determined to be above a predefined altitude threshold value.

Predicting a channel between a transceiver and a connected vehicle having a “main antenna”, dedicated to exchanges of payload data with the transceiver, and a “predictor antenna”, placed in front of the main antenna to predict the radio channel dealt with by the main antenna when reaching the current position of the predictor antenna. The method includes: selecting, using an estimate of the vehicle's speed and acceleration, for a multiplet of channel samples measured at the main antenna, a multiplet of channel samples measured at the predictor antenna, each sample of the predictor antenna being selected to correspond to a sample of the main antenna subsequently measured at the same position; calculating a criterion associating multiplets of samples measured at the main and predictor antennas; and selecting samples of the predictor antenna using a speed/acceleration pair optimizing the criterion, to predict the channel between the transceiver and main antenna.

Communication quality such as a delay time is stabilized when a plurality of communication devices on the same mobile object simultaneously perform communication. A wireless communication system that is mounted on a mobile object is a wireless communication system including a first communication device and a second communication device that are mounted on a first mobile object. When information is shared by mobile objects by transmitting packets based on information acquired from a network within the first mobile object to a communication device mounted on a second mobile object, the first communication device and the second communication device transmit packets having the same content by adopting the same communication method and using different channels, and a signal transmission timing from the second communication device is set to be later than a transmission timing from a communication device from the first communication device.

Method of resource selection where a selection window with a total number of resources is set. The method includes setting a sensing window and monitoring slots by decoding a physical sidelink control channel (PSCCH) and measuring a reference signal received power (RSRP), setting a threshold, excluding any restricted resources from the total number of resources, excluding any occupied resources from the total number of resources, and determining if an initial number of remaining resources is greater than or equal to an initial percentage of the total number of resources.

A method performed by a network node (160) includes serving a cell area by a first physical network node for a first time duration. The first physical network node uses an identifier of a logical network node. For a second time duration, the cell area is served by a second physical network node. The second physical network node uses the identifier of the logical network node. The first physical network node serves the cell area with a first frequency band and the second physical network node serves the cell area with a second frequency band.

A user equipment (UE), comprising: higher layer circuitry configured to receive first information to configure a sidelink bandwidth part (BWP) and second information to configure one or more resource pool for sidelink transmission and/or reception; transmitting circuitry configured to transmit a physical sidelink control channel (PSCCH) and a physical sidelink shared channel (PSSCH), wherein the first information includes a configuration of numerologies for the PSCCH and PSSCH; and the second information includes a configuration of one or more resource pools for the PSCCH and PSSCH within the sidelink BWP.

The present disclosure provides a paging method, a positioning information sending method, a core network node and a base station, and relates to the technical field of communication. The paging method is applied to the core network node in a satellite Internet communication system and comprises the following steps: acquiring the setting mode of the tracking area TA in the satellite Internet communication system; determining the base station for paging the terminal according to the setting mode; and sending a paging message to the base station; wherein the setting mode comprises one of the following setting mode: dividing the satellite Internet communication system one TA; setting at least two fixed TAs; and setting at least two non-fixed TAs.

A communication system includes a first communication device located onboard a first vehicle in a vehicle system formed from the first vehicle and at least a second vehicle, a second communication device located onboard the second vehicle in the vehicle system, and a first communication path extending between the first and second communication devices and established using a first communication medium. The first and second communication devices may share a security credential via the first communication path. The first and second communication devices also may establish a secure second communication path between the first and second communication devices using the security credential that is shared via the first communication path. The second communication path established by the first and second communication devices uses a different, second communication medium extending between the first and second communication devices.

An anchor vehicle includes a network device configured to access a network using dedicated wireless connectivity, and a processor. The processor is programmed to: receive a request for accessing the network using the dedicated wireless connectivity from a connected vehicle; determine whether the connected vehicle has consented to monitoring compliance with a warranty of the connected vehicle; and provide, to the connected vehicle, access to the dedicated wireless connectivity via the anchor vehicle in response to determining that the connected vehicle has consented to monitoring the compliance with the warranty of the connected vehicle.

Disclosed is a method by which a V2X communication device for a vehicle transmits a CPM message. The method for transmitting the CPM message comprises the steps of: determining a transmission mode of the CPM message for generating a collective perception for at least one object detected by the V2X communication device; and transmitting the CPM message on the basis of the transmission mode. The CPM message corresponds to a dynamic CPM message for transmitting dynamic data or a full CPM message for transmitting the dynamic data and static data, wherein the dynamic CPM message can include a dynamic container containing the dynamic data, and the full CPM message can include the dynamic container containing the dynamic data and the static container containing static data.