A wireless communication apparatus comprising: a frame configuration circuit that generates a transmission frame including DMG beacons, wherein sector ID fields in SSW fields included in the respective DMG beacons indicate one or more transmit sectors used for directional transmissions of the respective DMG beacons, and a field different from the sector ID field included in each DMG beacon indicates whether or not there is quasi-omni transmission; and a transmission wireless circuit that performs, by using the transmit sector indicated by the sector ID field, directional transmission on a first DMG beacon that is included in the DMG beacons and in which the field different from the sector ID field indicates non-quasi-omni transmission and performs quasi-omni transmission on a second DMG beacon that is included in the DMG beacons and in which the different field indicates quasi-omni transmission, in a BTI.

The present disclosure relates to a communication technique for fusing, with IoT technology, a 5G communication system for supporting a higher data transmission rate than a 4G system, and a system thereof. The present disclosure may be applied to an intelligent service such as a smart home, a smart building, a smart city, a smart car or a connected car, health care, digital education, retail, and security and safety related services on the basis of 5G communication technologies and IoT related technologies. A method for performing a vehicle communication service by a first terminal in a wireless communication system, according to the present disclosure, may comprise the steps of: receiving a first message related to the vehicle communication service from a network entity; determining a parameter of the vehicle communication service on the basis of the first message; receiving a second message related to the vehicle communication service from a second terminal; and determining whether to process the second message on the basis of the parameter of the vehicle communication service.

A terminal number estimating system includes: a plurality of receivers that receive a wireless signal transmitted from a plurality of terminal devices by frequency-division multiple access; a Fourier transform unit that performs a discrete Fourier transform on each wireless signal received by the plurality of reception means and outputs a discrete Fourier coefficient; and a terminal number estimation unit that estimates a position of each terminal device by clustering a resource block of each wireless signal based on each discrete Fourier coefficient.

A wireless communication device includes a communicator and a processor. The communicator which wirelessly communicates with a first communicator of an external device in a first communication standard and which wirelessly communicates with a second communicator of the external device in a second communication standard different from the first communication standard. The processor obtains association between identification information of the first communicator and identification information of the second communicator. To switch a current communicator which is one of the first and second communicators of the external device to a next communicator which is another of the first and second communicators, the processor specifies identification information of the next communicator based on the association, and establishes connection with the next communicator using identification information of the next communicator.

This disclosure relates to techniques for supporting message mapping via time and/or frequency indexing. For example, these techniques may be applied to device-to-device wireless communication. For example, device to device discovery may use message mapping via frequency indexing. A portion of the payload of a message, such as a discovery message, may be offloaded to a frequency and/or time index. A receiving device may determine the offloaded portion of the payload based on the frequency and/or time (e.g., subcarrier and/or slot) used to transmit the message.

Disclosed are techniques for wireless communication. In an aspect, an originator UE transmits a sidelink beam training (BT) reference signal (BTRS) a first number of times on each of a first set of beams, and a sidelink discovery message a second number of times on each of a second set of beams, wherein each beam from the second set of beams is associated with at least one beam from the first set of beams (e.g., 1:1 or N:1 mapping of first set of beams to second set of beams). At least one responder UE responds by transmitting, after the transmission of the sidelink BTRSs and the sidelink discovery messages, a BT response signal and a sidelink discovery response message on a beam corresponding to one of the first set of beams.

A station (STA) receives an indication from a first access point (AP) on one of a plurality of links that is not a non-primary link among the plurality of links comprising at least a primary link and the non-primary link. Based on the indication, the STA determines that: (i) the first AP is affiliated with a non-simultaneous-transmit-and-receive (NSTR) AP multi-link device (MLD), and (ii) a second AP, as a neighbor AP of the first AP, is affiliated with the NSTR AP MLD and is operating on the non-primary link.

A specific communication device may send specific identification information for identifying the specific communication device to an external via a communication interface, wherein the external device may display a screen including the specific identification information in a case where the external device receives the specific identification information from the specific communication device; and in a case where a specific condition including that the specific identification information is sent to the external is fulfilled, a state of the display unit may be changed from a first state to a second state, the first state being a state in which the display unit does not display the specific identification information, and the second state being a state in which the display unit displays the specific identification information.

A computer-readable instructions may cause the terminal device to: search for one or more communication device to receive, from each of the one or more communication devices, device information indicating the corresponding communication device; supply target device information to the OS program, wherein the OS program executes an establishing process using the target device information, the establishing process using the target device information including establishing a target connection with a target communication device; and in a case where target access point information is selected, supply the target access point information to the OS program, wherein the OS program obtains target wireless profile for connecting to a target wireless network formed by a target access point; and sends the obtained target wireless profile to the target communication device by using the established target connection.

Systems, methods, and instrumentalities are disclosed to manage interference caused by D2D communications. A wireless transmit receive unit (WTRU) may include a processor. The processor may be configured to perform one or more of the following. The processor may determine to send information using a device-to-device transmission via a resource pool from a plurality of resource pools. Each resource pool may be associated with a range of reference signal receive power (RSRP) values. The processor may determine a RSRP measurement of a cell associated with the WTRU. The processor may select a resource pool from the plurality of resource pools based on the RSRP measurement of the cell. The RSRP measurement of the cell may be within the range of RSRP values associated with the selected resource pool. The processor may send the information using the selected resource pool.