Embodiments of the present application are related to a method and apparatus for determining quasi co-location (QCL) reference signal (RS). According an embodiment of the present application, an exemplary method includes: receiving first configuration information indicating association between bandwidth part (BWP) and QCL RS; determining a first QCL RS associated with a first BWP, which is indicated by second configuration information or predefined in specification (s); and determining a second QCL RS associated with the first BWP based on the first QCL RS and the association between BWP and QCL RS.

A measurement feedback method includes: receiving, by a network device, capability information of a terminal and, in response to the capability information of the terminal, determining, by the network device, measurement feedback configuration information for the terminal; and sending, by the network device, the measurement feedback configuration information to the terminal.

A method of enabling communication between a user equipment (UE) and a non-terrestrial network (NTN), is described. The UE may be able to calculate a timing advance compensation. The timing advance compensation may be a differential or full timing advance compensation. An offset value, K.sub.offset, may be indicated to the UE. The K.sub.offset value may be used for timing relationships.

This disclosure relates generally to wireless communications and, more particularly, to systems and methods for maintaining signal and data connections from a mobile base station portion relative to a fixed network portion. In one embodiment, a method performed by a communication node gateway, includes: receiving a signal from a mobile communication node portion at a first dynamic port during a first duration of time; directing the signal from the first dynamic port to a static port associated with transport network layer information during the first duration of time; receiving the signal at a second dynamic port during a second duration of time after the first duration of time; and directing the signal from the second dynamic port to the static port during the second duration of time by using the transport network layer information.

A GSM satellite communication system is in communication with a first satellite having a first field of view including a first plurality of cells in which a plurality of active User Equipment (UEs) are located. The plurality of active UEs are in direct communication with the first satellite. The satellite communication system includes a first feeder link and a first tracking antenna configured to communicate with the plurality of active UEs via the first satellite directly serving the first plurality of cells; a first processing device configured to communicate with the plurality of active UEs; and a second processing device configured to normalize delay for a plurality of beam centers of the first plurality of cells, and provide the normalized delay to the first processing device.

A GSM satellite communication system is in communication with a first satellite having a first field of view including a first plurality of cells in which a plurality of active User Equipment (UEs) are located. The plurality of active UEs are in direct communication with the first satellite. The satellite communication system includes a first feeder link and a first tracking antenna configured to communicate with the plurality of active UEs via the first satellite directly serving the first plurality of cells; a first processing device configured to communicate with the plurality of active UEs; and a second processing device configured to normalize delay for a plurality of beam centers of the first plurality of cells, and provide the normalized delay to the first processing device.

Wireless devices, base stations, and other network devices and method are described that improve link level performance in a non-terrestrial network (NTN). In an embodiment, a method includes one or more of: configuring an NB-IoT (narrowband-Internet of Things) NPSS (Narrowband Primary Synchronization Signal) transmissions in multiple spot beams overlapping in time and frequency, configuring LTE PSS (Primary Synchronization Signal) transmissions in multiple beams overlapping in time and frequency, configuring NR (New Radio) PSS transmissions (e.g., which support the same shift of a respective M-sequence that defines the NR PSS) in multiple beams overlapping in time and frequency, configuring NR PSS transmissions (e.g., which support the same shift of a respective M-sequence that defines the NR PSS) in multiple beams configured to share the same SS/PBCH block index overlapping in time and frequency.

Provided are a transmission configuration method and apparatus, a communication node, a communication device and a computer-readable storage medium. The method includes steps described below, a communication node determines a downlink signaling indication for indicating a transmission configuration of a communication device, where the downlink signaling indication includes transmission state information, and the transmission state information includes correction indication information; and the communication node sends the downlink signaling indication.

The present disclosure provides example communications methods and devices. One example communication method includes generating a first message by a first communications device. The first message is sent by the first communications device to a second communications device, where the first message indicates configuration information of the first communications device and a first duration, and the first duration is a duration in which the second communications device stores the configuration information of the first communications device.

Methods, systems, and devices for wireless communication are described. A communication device, such as a user equipment (UE) may identify information for transmitting to a base station of a non-terrestrial network. The UE may identify that one or more resources allocated for transmitting the information are available based at least in part on identifying the information. The one or more resources include one or more types of uplink resources including physical random access channel (PRACH) resources or physical uplink shared channel (PUSCH) resources for the random access procedure, a PUSCH for a scheduling request (SR), or a physical uplink control channel (PUCCH) for a configured grant, or a combination thereof As a result, the UE may transmit, to the base station, a message over the one or more resources allocated for the information based at least in part on identifying the one or more resources.