Methods, systems, and devices for wireless communications are described. A network entity may support communications with a user equipment (UE) that is moving at a first speed that meets or exceeds a threshold via a cell that is configured to support such communications, which may be referred to as a high speed train (HST) cell. The network entity and the UE may support cell acquisition that prioritizes camping on an HST cell over a non-HST cell. The UE and the network entity may communicate acquisition signaling associated with establishing a connection with the network entity using a first frequency associated with an HST cell and a non-HST cell. Based on an identifier indicating that the HST cell is an HST cell, the UE may prioritize the HST cell over the non-HST cell during cell acquisition and establish the connection with the network entity via the HST cell.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment may measure a beam, according to a measurement configuration, to determine a channel condition value of the beam, modify the channel condition value based at least in part on at least one of one or more beam characterizations, a derivation of a beamforming gain value, or an estimation of the beamforming gain value, and transmit, to a base station, a measurement report indicating the modified channel condition value. Numerous other aspects are provided.

A satellite network comprises networks nodes including multiple satellites, multiple gateways, additional servers and a mobile vehicle (e.g., an aircraft). All of (or a subset) of the network nodes include switches. The network implements a software defined network that includes a mobility manager as part of the management plane, a network controller as part of the control plane, and the switches on the network nodes as the data plane. In one embodiment, the switches communicate using an Open Flow communications protocol and make routing decisions based on flow tables. The mobility manager communicates with, and manages, the switches via the network controller. The mobility manager proactively generate updates to flow tables based on satellite ephemeris data for the multiple satellites and itinerary data for the aircraft, and pushes the updates to the switches in response to determining that the aircraft needs to be handed off between satellites.

A base station is provided. The base station comprises a processor configured to receive beam related information from a user equipment (UE), determine a position of the UE in response to the beam related information and acquire a video stream from at least on video capturing device configured on the base station in response to the position.

User equipment (UE) selection of contention-free random access (CFRA) and contention-based random access (CBRA) for handover processing is discussed. The aspects include receiving a random access configuration at the UE including configuration for CFRA and CBRA. The UE will determine a first random access resource, wherein the first random access resource maps to one or more beams from a target base station. The UE may initiate a random access request using the CFRA when the first random access resource is a contention-free resource, and initiate the random access request using the CBRA when the first random access resource is a contention-based resource.

A wireless device (16) is configured for use in a wireless communication system (10). The wireless device (16) in this regard is configured to obtain, for each of one or more cells, information derived from a measure of dispersion of the values of received signal measurements respectively performed by the wireless device (16) on different transmit beams of the cell. The wireless device (16) is also configured to use the obtained information to select, or to assist network equipment (500A, 500B) to select, from the one or more cells a target cell to which the wireless device (16) is to change. The wireless device (16) is further configured to perform a cell change to the selected target cell.

A system and method for communicating channel state information reference signal (CSI-RS) in a communication network. A cell such as an eNodeB (eNB) or a transmit-receive-point (TRP) may transmit to a user equipment (UE) one or more synchronization signal (SS) blocks according to one or more beam directions available to the cell. Each beam direction may correspond to one or more antenna ports, and each SS block may correspond to an SS index. The cell may then transmit a CSI-RS signal configured according to the one or more antenna ports and the one or more SS blocks. In a different embodiment, the cell may select antenna ports of a neighbor cell for the CSI-RS signal based on a channel state measurement report of the neighbor cell received from the UE.

Methods, devices and computer programs for determining new transmit directions to use for beamformed transmissions in case the link quality of an existing direction falters. A transmitting communication device and a receiving communication device cooperate via a beam tracking procedure to determine a new suitable transmit direction to use for upcoming beamformed transmissions. Information relating to the beam tracking procedure is communicated over an existing link that enables communication between the transmitting and receiving communication devices. The receiving communication device provides the transmitting communication device with information about a beam scan performed in order to detect tracking beams transmitted by the transmitting communication device. This information allows the transmitting communication device to determine suitable transmit directions to use.

Methods respectively implemented in a network device and a terminal device for facilitating handover of the terminal device served by the network device to a target beam and/or network device. The method in the network device comprises transmitting information on configurations for a set of candidate target beams and/or network devices to the terminal device before the handover of the terminal device is triggered. The method further comprises transmitting a handover command to the terminal device to trigger the handover of the terminal device. The handover command contains an identifier for identifying, from the transmitted information on the configurations for the candidate target beams and/or network devices, the information on the configuration for the target beam and/or network device. The disclosure also provides a network device and a terminal device that perform the above methods respectively.

Disclosed is a method performed by a network equipment (16) for controlling handover of a User Equipment, UE, (2) from a source network node (1) to a target network node (3a), the method comprises providing (S1), for the UE (2) and for the target network node (3a), information comprising a representation of a UE specific sequence, wherein the UE specific sequence is to be incorporated in a signal, said signal to be transmitted by the target network node (3a) to enable the UE to initiate a radio link establishment procedure with the target network node (3a) based on a reception of a signal comprising said UE specific sequence. Also disclosed are corresponding devices and computer programs. Further disclosed are cooperating methods, and corresponding devices and computer programs, performed by a UE (2) and a network node (3a) during handover of the UE (2) from the source network node (1) to the target network node.