A wireless network data communication system includes a plurality of slave nodes and a central processing unit. Each slave node is assigned thereto a transmission time interval and is configured to transmit data based on its assigned transmission time interval. The central processing unit is in signal communication with the slave nodes to receive transmitted data. The central processing unit is further configured to identify a given slave node from among the plurality of slave nodes based on a comparison between an arrival time at which transmitted data was received and the transmission time intervals assigned to each slave node.

Embodiments are presented herein of apparatuses, systems, and methods for utilizing a flexible slot indicator in wireless communication. A base station (BS) may establish communication with a first user equipment device (UE). The BS may determine a transmission direction for each of a plurality of symbols included in one or more slots. The BS may transmit a slot format indicator (SFI) to the UE. The SFI may indicate the transmission direction for each of the plurality of symbols included in one or more slots. The BS and the UE may perform communication during the one or more slots according to the determined transmission direction.

Proposed are a method and an apparatus for transmitting a signal by performing MIMO beamforming in a wireless LAN system. Specifically, a first STA performs MIMO beamforming during a second STA and TDD-based SP. The first STA transmits a signal to the second STA on the basis of a result of the MIMO beamforming. The SP includes a plurality of TDD slots. The MIMO beamforming includes a first sub-step and a second sub-step. In the first sub-step, after receiving a first MIMO beamforming setup frame from the second STA, the first STA transmits a second MIMO beamforming setup frame in the first allocated TDD slot among the TDD slots allocated to the first STA. In the second sub-step, after receiving a first MIMO beamforming feedback frame from the second STA, the first STA transmits a second MIMO beamforming feedback frame in a first allocated TDD slot among the TDD slots allocated to the first STA.

A transmission timing information sending method, a transmission timing information receiving method, and related apparatus are disclosed. In an embodiment a method includes configuring, by a base station, higher layer signaling, wherein the higher layer signaling comprises at least one transmission timing set comprising at least one transmission timing value, and the at least one transmission timing set is related to at least one of the following factors: a subcarrier width, a TDD manner, or a terminal capability, sending, by the base station, the higher layer signaling to a terminal, determining, by the base station, downlink control information (DCI), wherein the DCI is used to instruct the terminal to determine the transmission timing value in the at least one transmission timing set, wherein the determined transmission timing value is a slot that the terminal is instructed to use when sending feedback information and sending, by the base station, the DCI to the terminal.

A communication protocol overlay that governs wireless data communications between an access point and subscribers. The communication protocol overlay includes a repeating pattern of superframes, each superframe including frames. Each frame includes a beacon emitted by an access point in a downlink communication to the subscribers at a beginning of the frame. Each frame further includes communication slots following the beacon. Each of the communication slots is uniquely assigned to one of the subscribers, permitting the subscriber to perform an uplink communication to the access point, within the communication slot. The beacon is precisely timed, and each of the communication slots follows the beacon with a specified temporal offset. A single superframe of the repeating pattern of superframes serves all subscribers by providing at least one communication slot to each of the subscribers.

An active antenna system includes: a plurality of antennas; a plurality of switches respectively connected to the antennas, the switches being configured to switch between transmission signal lines and reception signal lines to perform Time Division Duplex; a plurality of transmitter-receivers respectively connected to the transmission signal lines and the reception signal lines; a calibration transmitter connected to the transmission signal lines; a calibration receiver connected to the reception signal lines; and a control unit configured to carry out, during a receiving time of the Time Division Duplex, reception calibration of each of the transmitter-receivers based on a signal transmitted by the calibration transmitter and received by the transmitter-receivers, and, during a transition time from reception to transmission, carry out transmission calibration of each of the transmitter-receivers based on a signal transmitted by the transmitter-receivers and received by the calibration receiver.

A communication protocol overlay that governs wireless data communications between an access point and subscribers. The communication protocol overlay includes a repeating pattern of superframes, each superframe including frames. Each frame includes a beacon emitted by an access point in a downlink communication to the subscribers at a beginning of the frame. Each frame further includes communication slots following the beacon. Each of the communication slots is uniquely assigned to one of the subscribers, permitting the subscriber to perform an uplink communication to the access point, within the communication slot. The beacon is precisely timed, and each of the communication slots follows the beacon with a specified temporal offset. A single superframe of the repeating pattern of superframes serves all subscribers by providing at least one communication slot to each of the subscribers.

A user equipment for performing radio communication with a base station in accordance with dynamic TDD (Time Division Duplex) is disclosed. An aspect of the present invention relates to a user equipment including a transmission and reception unit that transmits a radio signal to and receives a radio signal from a base station in accordance with dynamic TDD; and a transmission power configuration unit that configures uplink transmission power toward the base station, wherein the transmission power configuration unit configures the uplink transmission power in accordance with a dedicated scheme, a group common scheme or a combined scheme of the dedicated scheme and the group common scheme.

This document describes methods, devices, systems, and means for performing a regrouping of a user equipment (UE) (113) between user equipment-coordination sets (UECS) by a base station (121) in which the base station (121) determines to regroup a user equipment (113) from a source UECS to a target UECS and transmits a release message to a coordinating UE (111) of the source UECS requesting the coordinating UE (111) of the source UECS to release the user equipment (113) from the source UECS (605). The base station (121) transmits a request message to a coordinating UE (114) of the target UECS requesting the coordinating UE (114) of the target UECS to add the user equipment (113) to the target UECS (610), and transmits a regrouping message to the user equipment (113) that is effective to direct the user equipment (113) is to perform a regrouping from the source UECS to the target UECS (615).

The present invention relates to a system that includes a transmission/reception point and a user equipment having different configurations in inter-band and performs a TDD (Time Division Duplex) method.