The disclosure relates to an overlapped multiplexing modulation method, apparatus, and system. An initial envelope waveform that is smooth in a time domain or frequency domain is generated based on design parameters; the initial envelope waveform is shifted in the time domain or frequency domain at a preset spectrum interval based on times of overlapped multiplexing, to obtain subcarrier envelope waveforms; an input digital signal sequence is converted into a positive-negative symbol sequence; each symbol in the positive-negative symbol sequence is multiplied by a subcarrier envelope waveform corresponding to the symbol, to obtain modulated envelope waveforms of subcarriers; the modulated envelope waveforms of the subcarriers are superimposed in the time domain or frequency domain, to obtain a time-domain or frequency-domain complex modulated envelope waveform; and the time-domain or frequency-domain complex modulated envelope waveform is transformed, to obtain a time-domain or frequency-domain complex modulated envelope waveform.

The disclosure relates to an overlapped multiplexing modulation method, apparatus, and system. An initial envelope waveform that is smooth in a time domain or frequency domain is generated based on design parameters; the initial envelope waveform is shifted in the time domain or frequency domain at a preset spectrum interval based on times of overlapped multiplexing, to obtain subcarrier envelope waveforms; an input digital signal sequence is converted into a positive-negative symbol sequence; each symbol in the positive-negative symbol sequence is multiplied by a subcarrier envelope waveform corresponding to the symbol, to obtain modulated envelope waveforms of subcarriers; the modulated envelope waveforms of the subcarriers are superimposed in the time domain or frequency domain, to obtain a time-domain or frequency-domain complex modulated envelope waveform; and the time-domain or frequency-domain complex modulated envelope waveform is transformed, to obtain a time-domain or frequency-domain complex modulated envelope waveform.

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 wireless device (14) is configured to perform a random access procedure (16) for random access by the wireless device (14) to a wireless communication system (10). The random access procedure (16) includes multiple messages in sequence. The wireless device (14) is configured to determine a carrier on which a downlink message (18) in the random access procedure (16) is to be received by the wireless device (14), from amongst multiple different carriers (20) which are configurable as said carrier, based on configuration information (22) received from a radio network node (12) indicating said carrier. The downlink message (18) occurs in the random access procedure (16) subsequent to an initial message in the sequence. The wireless device (14) is also configured to receive the downlink message (18) on the determined carrier.

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 base station allocates downlink transmission powers to user equipments according to the reception qualities of the user equipments. The base station transmits a mixed data signal in which multiple data signals that are addressed to multiple user equipments and are not orthogonal to each other are mixed, and transmits multiple control signals to the multiple user equipments such that each user equipment can decode the data signal addressed to that user equipment using the control signal corresponding to that user equipment. Each control signal is scrambled using the identifier of the user equipment corresponding to that control signal. With a period longer than the transmission period for the control signal, the base station notifies the multiple user equipments of identifier information indicating multiple identifiers, and thus the user equipment can descramble a control signal for another user equipment to which an interference data signal with a higher transmission power is addressed.

A base station allocates downlink transmission powers to user equipments according to the reception qualities of the user equipments. The base station transmits a mixed data signal in which multiple data signals that are addressed to multiple user equipments and are not orthogonal to each other are mixed, and transmits multiple control signals to the multiple user equipments such that each user equipment can decode the data signal addressed to that user equipment using the control signal corresponding to that user equipment. Each control signal is scrambled using the identifier of the user equipment corresponding to that control signal. With a period longer than the transmission period for the control signal, the base station notifies the multiple user equipments of identifier information indicating multiple identifiers, and thus the user equipment can descramble a control signal for another user equipment to which an interference data signal with a higher transmission power is addressed.

Techniques are described for wireless communication. One method includes searching for a synchronization channel on a first raster point of a frequency raster identified for synchronization channel transmission. The frequency raster includes a plurality of raster points in a radio frequency spectrum. The method also includes identifying a pull-in signal on the first raster point; determining, from the pull-in signal, a second raster point of the frequency raster on which the synchronization channel is transmitted; and receiving the synchronization channel on the second raster point. Another method includes transmitting the pull-in signal and the synchronization channel.

Techniques are described for wireless communication. One method includes searching for a synchronization channel on a first raster point of a frequency raster identified for synchronization channel transmission. The frequency raster includes a plurality of raster points in a radio frequency spectrum. The method also includes identifying a pull-in signal on the first raster point; determining, from the pull-in signal, a second raster point of the frequency raster on which the synchronization channel is transmitted; and receiving the synchronization channel on the second raster point. Another method includes transmitting the pull-in signal and the synchronization channel.