A transmitter and a method therein for transmitting discovery signals to a receiver. The transmitter and the receiver are comprised in a radio communications system. The transmitter transmits two or more discovery signals over two or more directions. Each discovery signal is configured to span over a fraction of a carrier bandwidth.

A transmitter and a method therein for transmitting discovery signals to a receiver. The transmitter and the receiver are comprised in a radio communications system. The transmitter transmits two or more discovery signals over two or more directions. Each discovery signal is configured to span over a fraction of a carrier bandwidth.

Certain aspects of the present disclosure generally relate to wireless communication. In some aspects, a base station may identify a synchronization signal (SS) block index associated with a SS block; scramble a physical broadcast channel (PBCH), associated with the SS block, based at least in part on the SS block index; and transmit the SS block including a tertiary synchronization signal (TSS) and the PBCH, wherein the TSS includes information that identifies the SS block index associated with the SS block, and wherein the TSS is frequency division multiplexed with the PBCH in two or more orthogonal frequency-division multiplexed (OFDM) symbols of the SS block. Numerous other aspects are provided.

Certain aspects of the present disclosure generally relate to wireless communication. In some aspects, a base station may identify a synchronization signal (SS) block index associated with a SS block; scramble a physical broadcast channel (PBCH), associated with the SS block, based at least in part on the SS block index; and transmit the SS block including a tertiary synchronization signal (TSS) and the PBCH, wherein the TSS includes information that identifies the SS block index associated with the SS block, and wherein the TSS is frequency division multiplexed with the PBCH in two or more orthogonal frequency-division multiplexed (OFDM) symbols of the SS block. Numerous other aspects are provided.

A method in a transmitter station for establishing a wireless link with a receiver station includes: sending beamforming training data to the receiver station; responsive to sending the beamforming training data, receiving from the receiver station: beamforming feedback data; and a beamforming feedback mode indicator selected from (i) a multi-subcarrier feedback mode, and (ii) a single carrier feedback mode; when the beamforming feedback mode indicator corresponds to the single carrier feedback mode, obtaining beamforming parameters based on the beamforming feedback data.

A method in a transmitter station for establishing a wireless link with a receiver station includes: sending beamforming training data to the receiver station; responsive to sending the beamforming training data, receiving from the receiver station: beamforming feedback data; and a beamforming feedback mode indicator selected from (i) a multi-subcarrier feedback mode, and (ii) a single carrier feedback mode; when the beamforming feedback mode indicator corresponds to the single carrier feedback mode, obtaining beamforming parameters based on the beamforming feedback data.

A wireless communication method, a network device and a terminal device are provided. The method comprises: transmitting a first control channel in a first period of time, wherein the first control channel carries scheduling information of a first data channel; receiving or transmitting the first data channel in a second period of time according to the scheduling information of the first data channel; transmitting a second control channel in a frequency division multiplexing manner with the first data channel at part time of the second period of time, wherein a data channel scheduled by the second control channel does not include the first data channel, and a starting position of the part time is not earlier than an ending position of the first period of time.

A hybrid time-division multiplexing comprises: S1, determining a length of a single time cycle; S2, formulating a working state table corresponding to the length of the single time cycle; S3, dividing the single time cycle into a synchronous time-division multiplexing time section and/or a statistical time-division multiplexing time section with a ratio of the synchronous time-division multiplexing time section to the single time cycle no less than 0 and no greater than 1; and S4, according to the working state table, accessing the channel and transmitting information by the MAC protocol user adopting synchronous time-division multiplexing in the synchronous time-division multiplexing time section, and/or accessing the channel and transmitting information by the MAC protocol user adopting statistical time-division multiplexing in the statistical time-division multiplexing time section. The method realizes compatibility of the above two communication methods on one chip, and satisfies user's requirements on real-time communication and a high channel utilization rate.

A hybrid time-division multiplexing comprises: S1, determining a length of a single time cycle; S2, formulating a working state table corresponding to the length of the single time cycle; S3, dividing the single time cycle into a synchronous time-division multiplexing time section and/or a statistical time-division multiplexing time section with a ratio of the synchronous time-division multiplexing time section to the single time cycle no less than 0 and no greater than 1; and S4, according to the working state table, accessing the channel and transmitting information by the MAC protocol user adopting synchronous time-division multiplexing in the synchronous time-division multiplexing time section, and/or accessing the channel and transmitting information by the MAC protocol user adopting statistical time-division multiplexing in the statistical time-division multiplexing time section. The method realizes compatibility of the above two communication methods on one chip, and satisfies user's requirements on real-time communication and a high channel utilization rate.

Data transmissions are scheduled from internet of things (IoT) user equipment (UEs) to a base station (BS) that serves those IoT UEs in a cellular network. A BS may broadcast synchronization information to the IoT UEs that allows the BS to calculate and use a schedule for receiving data transmissions from the UEs. This information can include a total number of the IoT UEs being serviced, a length of a spreading code to use in the schedule, a time domain periodicity of available resources, and a maximum number of the IoT UEs that can send data to the BS at one time. Each IoT UE can independently apply a mathematical operation to the broadcast information it receives to calculate and use the schedule. The BS can receive the data transmissions from each of the IoT UEs according to that schedule.