Disclosed herein are a method of performing synchronization in a distributed wireless communication system, and a terminal supporting the same. A distributed wireless communication system includes a plurality of networks. Time resources of each of a plurality of networks are divided into a synchronization slot, a discovery slot, a peering slot, and a data slot. A first terminal belonging to a first network determines whether a synchronization signal is received from a terminal belonging to a second network in the data slot of the first network. The first terminal detects whether it has met the second network that is out of synchronization with the first network if the synchronization signal is determined to have been received.

An uplink synchronization processing method, a User Equipment (UE), and a base station are provided. The method includes: receiving a component carrier (CC) uplink synchronization indication message sent by a base station, where the uplink synchronization indication message carries identification information of one or multiple newly configured CCs; sending synchronization signaling to the base station when determining that the uplink synchronization needs to be executed on all or a part of the one or multiple newly configured CCs corresponding to the identification information; and receiving a time advanced (TA) adjusting message that is sent by the base station according to the synchronization signaling, and applying a TA value carried in the TA adjusting message to the CC on which the uplink synchronization needs to be executed.

A data transmission method includes: acquiring a time delay parameter corresponding to an advanced interactive data packet, and acquiring time delay monitoring information between the next generation nodeB and a user equipment; acquiring a transmission delay of the advanced interactive data packet on a network side in response to identifying that a data packet transmitted by a user plane function belongs to data sub-packets obtained by splitting the advanced interactive data packet; predicting, according to the time delay parameter, the time delay monitoring information, and the transmission delay of the advanced interactive data packet on the network side, whether transmitting the data sub-packets to the user equipment meets a time delay desirable; and stopping, in response to determining that transmitting the data sub-packets to the user equipment does not meet the time delay desirable, transmitting the data sub-packets obtained by splitting the advanced interactive data packet to the user equipment.

The subject matter disclosed herein relates to position location in a wireless communication system, and may more particularly relate to position location for a mobile station.

Monitoring and mass notification systems, such as fire alarm systems, for use in occupied structures, and more particularly to wireless monitoring and mass notification systems include wireless base units that can be modular in design. This allows horns, mini horns, strobes, and audio messaging modules (e.g., speakers) to be physically plugged into the wireless base unit creating a unit with the appearance of a single physical unit. Preferably standardized plugs are used. In some cases, visual and audio modules (i.e., notification devices) have their own battery pack or external power interface. Each wireless base unit can optionally function as a repeater if it has dual transceivers (master transceiver and slave transceiver).

Monitoring and mass notification systems, such as fire alarm systems, for use in occupied structures, and more particularly to wireless monitoring and mass notification systems include wireless base units that can be modular in design. This allows horns, mini horns, strobes, and audio messaging modules (e.g., speakers) to be physically plugged into the wireless base unit creating a unit with the appearance of a single physical unit. Preferably standardized plugs are used. In some cases, visual and audio modules (i.e., notification devices) have their own battery pack or external power interface. Each wireless base unit can optionally function as a repeater if it has dual transceivers (master transceiver and slave transceiver).

The present document discloses a method and a system for determining a delay difference, and a base station and UE, the method includes: a serving cell receiving information of time measured by a neighboring cell at which uplink channel/signal information of UE for determining a synchronization delay is received; and the serving cell determining a synchronization delay difference between the UE to the serving cell and the UE to the neighboring cell according to information of time measured by the serving cell at which the uplink channel/signal information of the UE for determining the synchronization delay is received, and the information of time measured by the neighboring cell and at which the uplink channel/signal information of the UE for determining the synchronization delay is received, wherein the uplink channel/signal information measured by the serving cell is the same as the uplink channel/signal information measured by the neighboring cell.

Systems, methods, and apparatuses for sounding reference signal (SRS) management in carrier aggregation (CA) are described. A user equipment (UE) may be scheduled for overlapping (e.g., concurrent) transmissions of SRS and uplink control or data on different cells of a CA configuration. In some cases, the SRS transmission may be dropped (e.g., the UE may refrain from transmitting a scheduled SRS). While in some cases, the UE may transmit both SRS and another uplink message in overlapping time intervals on different cells (e.g., SRS may be transmitted concurrently with another uplink message). A determination of whether to transmit or drop SRS may be based on whether the different cells have different cyclic prefix (CP) lengths or on whether the SRS is scheduled to be transmitted in a special subframe of a time division duplexing (TDD) configuration, for example.

This application provides a communication method and a communication apparatus. In one example, a first physical layer protocol data unit (PPDU) is sent over a first link, where the first PPDU carries a trigger frame. A second PPDU is sent over a second link. An end time of sending the second PPDU is not earlier than a first time and not later than a second time, the first time is related to an end time of sending the first PPDU and a state turnaround time, and the second time is related to the end time of sending the first PPDU and a short interframe space (SIFS) time.

A method includes receiving, by a user equipment (UE), a first signal from a first apparatus, the first signal comprising a first data for presentation by a second apparatus and a second data for presentation by a third apparatus, the first data and the second data being synchronized with each other in time. The UE extracts the first and second data from the first signal, and determines a timing for transmitting a second signal that comprises the first data to the second apparatus and for transmitting a third signal that comprises the second data to the third apparatus, the timing configured to approximately synchronize in time presentation of the first data and second data by the respective second and third apparatuses. The UE transmits the second signal to the second apparatus based on the timing, and transmits the third signal to the third apparatus based on the timing.