Methods for aligning sending of a network system clock time to a wireless device with initiating a propagation delay compensation procedure for the wireless device. An example method, in a network node, comprises determining that a propagation delay compensation procedure for the wireless device is to be initiated or has been initiated, and sending an indication of a network system clock time to the wireless device in association with the propagation delay compensation procedure.

A method performed by user equipment, including: step A of acquiring time-domain configuration information and/or time-domain indication information; and step B of determining timing-related information according to the time-domain configuration information and/or the time-domain indication information and/or other information.

Methods and apparatuses are described for configuring a downlink (DL) reference signal (RS) for an electronic device (ED). Configuration information associated with the DL RS is received in a first communication from a location management function (LMF) via LTE positioning protocol (LPP). In a communication from a serving cell via radio resource control (RRC), an identifier (ID) of the DL RS and a cell ID of a cell that originates the DL RS are received. The configuration information received in the first communication also includes the ID of the DL RS and the cell ID. A sounding reference signal (SRS) is transmitted to the cell identified by the cell ID, according to path loss (PL) information or spatial domain transmission filter (TF) information associated with the DL RS.

The present disclosure relates to methods and apparatus for determining an initial bandwidth part. One example method includes determining a frequency resource of a first initial BWP, where the frequency resource of the first initial BWP is included in a frequency resource of a second initial BWP, the frequency resource of the first initial BWP corresponds to a first-type terminal device, the frequency resource of the second initial BWP corresponds to a second-type terminal device, and the terminal devices of two types have different capabilities.

According to an embodiment, an electronic device may include: a wireless communication circuit for performing short-range wireless communication with at least one external electronic device; a memory; and a processor operatively connected to the wireless communication circuit and the memory. The processor may perform the short-range wireless communication with the at least one external electronic device via the wireless communication circuit, form a first neighbor awareness networking (NAN) cluster with the at least one external electronic device, on the basis of the short-range wireless communication, transmit a short-range wireless signal to the at least one external electronic device included in the first NAN cluster, and inactivate an NAN cluster merging function of the at least one external electronic device, using the short-range wireless signal. Various other embodiments may be possible.

Methods and apparatus are provided for a UE to determine a UL spatial relation for an UL transmission in response to an unknown UL spatial relation switch. The UE may determine whether the UL spatial relation is based on an SRS transmission in UL, a CSI-RS in DL, or an SSB in the DL. If the UL spatial relation is based on the SRS transmission, the UE may select the UL spatial relation for the UL transmission corresponding to a Tx beam of the SRS transmission. If the UL spatial relation is based on the CSI-RS or the SSB, the UE may select the UL spatial relation for the UL transmission based on whether the unknown UL spatial relation switch s due to a corresponding resource for beam training not being configured by a communication network or a corresponding beam information being expired.

Methods, systems, and devices for wireless communications are described. A serving base station or a serving satellite may transmit a timing configuration to the UE based on a reference unit, such as a location at a beam center for a respective satellite, a threshold distance relative to the beam center for the respective satellite, a reference time, or any combination thereof. In some cases, the UE may monitor for one or more SSBs from the neighboring satellites according to the timing configuration and a respective propagation delay between the UE and each of the neighboring satellites. The UE may measure the SSBs according to the measurement gap and measurement window in the timing configuration. In some examples, the UE may perform a cell handover procedure or a cell reselection procedure based on measuring the SSBs.

A base station may transmit, to a UE, at least one of the SS, the PBCH, the CORESET, or the SIB, via the plurality of resources based on the indication of the at least one initial access structure. In some aspects, the SS may be time-division multiplexed with the PBCH and may be frequency-division multiplexed with the CORESET and the SIB. In one aspect, the CORESET may be time-division multiplexed with the SIB. In another aspect, the CORESET may be frequency-division multiplexed with the SIB. In some aspects, at least one switching gap may be configured after the at least one initial access structure, the at least one switching gap being configured based on an SCS.

An apparatus including a plurality of antenna panels; circuitry configured for receiving a synchronization signal burst including a plurality of synchronization signal blocks; circuitry for configuring, for a first sample, each of the plurality of antenna panels to be switched in alternating manner to measure received signal power level of each of the plurality of synchronization signal blocks; circuitry for configuring, for a predetermined number of subsequent samples, each of the plurality of antenna panels to be switched in alternating manner to measure the received signal power level of the synchronization signal block providing a highest received signal power level for said antenna panel in the first sample; and circuitry configured for sending a report of the measured received signal power level of said synchronization signal block to a network element.

Techniques for determining a discontinuous reception configuration are disclosed. A user equipment may receive a discontinuous reception configuration from a network entity. The user equipment may select one or more discontinuous reception parameters to modify based at least in part on the received indication of a particular data burst class to be transmitted. The user equipment may receive a data burst and a selection command from the network entity. The user equipment selects one or more discontinuous reception parameters to modify based at least in part on the received indication of whether to apply the one or more adaptive parameters after the transmission of a current data burst is complete.