Methods and systems are provided that facilitate sidelink (SL) retransmission scheduled by the network if a SL transmission of a transport block (TB) is unsuccessful. Signalling is used by the network to send a configured grant of transmission resources available for SL transmissions by the UE that repeat on a periodic basis within each of period. The UE makes SL transmissions during one of the periods by transmitting one or more SL transmissions of at least one transport block using the configured resources. The network can schedule a retransmission by transmitting a downlink control information (DCI) to schedule a SL retransmission of one of the transmitted TB. The UE transmits a SL transmission containing a retransmission of the transport block using resources specified in the DCI. The UE transmits a sidelink control information associated with each SL transmission, containing a HARQ process ID for the SL transmission.

A reverse trigger system of multiple access point (multi-AP) operation and an Access Point (AP) are provided. The reverse trigger system includes: a common station; an initializer AP configured to send a trigger announcement to the common station, wherein the common station sends a trigger frame in response to receiving the trigger announcement; and at least one first coordinated AP configured to send first data in response to receiving the trigger frame, wherein the initializer AP is configured to send second data in response to receiving the trigger frame. Embodiments of the present disclosure may enable joint and synchronous data transmission between APs which cannot communicate with each other directly.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a network entity may receive, from a relay node via a radio access link, information indicating a link layer identifier of the relay node associated with a relay service, wherein the relay node is associated with a radio access identifier. The network entity may configure a relay service with the relay node and a remote node using a mapping between the radio access identifier and the link layer identifier. Numerous other aspects are described.

Aspects of the subject disclosure may include, for example, a device detecting a disruption in a backhaul network and connecting to an aerial device to establish an alternate backhaul connection. The device may incorporate all or a portion of a terrestrial base station and may tilt one or more antenna beams skyward to search for the aerial device. The device may then relay communications from user equipment to the aerial device. Other embodiments are disclosed.

Certain aspects of the present disclosure relate to assisting communications with low data payloads with relay nodes. An example method generally includes forming a first cluster with a first wireless node and one or more second wireless nodes, wherein each of the second wireless nodes has a low data rate demand relative to a system bandwidth. The method also includes determining to serve as a relay node for the first cluster, generating a first set of packets for uplink transmission to a base station, receiving a second set of packets from the one or more second wireless nodes, combining the first set of packets and the second set of packets into an uplink payload based on the determination, and transmitting, to the base station, the uplink payload based on the determination.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a first node may transmit, to a second node, a first message providing a first indication of integrated access and backhaul (IAB) capability. The first node may receive, from the second node and in response to the first message, a second message providing a second indication of IAB capability. The first node may establish an IAB capable connection with the second node based at least in part on the first message and the second message. Numerous other aspects are provided.

Performing random access process. In one aspect, there is a method performed by a network function. The method comprises the network function generating system information and the network function broadcasting the system information. The system information comprises i) first power information for use by at least a first set of communication devices and a second set of communication devices in determining a transmit power, and ii) second power information for use by the first set of communication devices, but not the second set of communication devices, in determining the transmit power.

A radio access network (RAN) control unit for determining a functional operation of a dynamic small cell, in particular an unplanned small cell, a nomadic node or a relay, in a radio communication network is disclosed. The radio communication network includes at least one network slice associated with at least one user equipment (UE) and at least one radio channel connecting the at least one UE to the radio communication network. The RAN control unit includes a processor configured to determine a functional operation of the dynamic small cell (DSC) based on information based on channel measurements of the at least one radio channel and/or requirement information of the at least network one slice, and/or estimated or measured performance of the RAN, and/or location information of the DSC.

A method of controlling communications within a wireless communications network is provided. The method comprises receiving, at a first infrastructure equipment acting as a donor node connected to a core network part of a wireless communications network, signals representing data from one or more others of infrastructure equipment, the data having been received at the one or more others of the infrastructure equipment from one or more communications devices or from other infrastructure equipment, and transmitting, by the first infrastructure equipment, the data from the one or more others of the infrastructure equipment to the core network part of the wireless communications network. At least one of the infrastructure equipment uses at least one spectral efficiency enhancing technique to receive the signals, the at least one spectral efficiency enhancing technique allowing the at least one infrastructure equipment to receive the signals in the backhaul communications link.

Embodiments of a User Equipment (UE) and methods of communication are generally described herein. The UE may attempt to detect synchronization signals, including Long Term Evolution (LTE) synchronization signals from eNBs, New Radio (NR) synchronization signals from gNBs, and sidelink synchronization signals (SLSSs) from other UEs. The UE may prioritize an LTE synchronization signal over an SLSS, and may prioritize an NR synchronization signal over an SLSS. If the UE does not detect an LTE synchronization signal or an NR synchronization signal, the UE may select an SLSS. The UE may prioritize an SLSS from a UE that is directly synchronized to an eNB or a gNB over an SLSS from another UE that is indirectly synchronized to an eNB or a gNB.