Methods, systems, and devices for wireless communications are described. Generally, a base station may transmit, to a victim user equipment (UE) a configuration message indication one or more resource for measuring cross-link interference (CLI) from an aggressor UE. The configuration message may include one or more cell parameters, which may include an indication of a relationship between the serving cell of the victim UE and the serving cell of the aggressor UE. The victim UE may determine the relationship between the serving cells based on the received cell parameters, and may perform CLI measurements based thereon. In some cases, the UE may adjust a CLI measurement window, or may prioritize some aggressor UEs, based on the determined relationship. The UE may also transmit a CLI measurement report to the base station.

A communication method includes receiving, by a first time domain resource, a first signal for synchronization and receiving, by at least one second time domain resource, a first message comprising one or both of cyclic prefix length information and resource configuration information for uplink transmission and downlink transmission, wherein a length of a time interval between the first time domain resource and each of the at least one second time domain resource is a positive-integer number of time domain resource units.

There is provided a multi-hop relay system including a transmission node and a relay node, communicating using a flooding method. The transmission node is configured to transmit a synchronization packet used to synchronize a plurality of relay nodes. The relay node is configured to perform first reception in a first period at every first cycle corresponding to the predetermined cycle, and second reception in a second period not less than a length of the predetermined period at every second cycle longer than the first cycle. The relay node performs the second reception if the synchronization packet cannot be received by the first reception, and if the synchronization packet is received by the second reception, stops the second reception and performs the first reception if the predetermined condition is determined to be satisfied, and if not, executes synchronization recovery processing.

Aspects of the present disclosure provide apparatus, methods, processing systems, and computer readable mediums to help conserve power for wireless repeaters. In some cases, a repeater may detect synchronization signal blocks (SSBs) for a set of one or more cells, obtain system information for one or more cells of the set, and forward one or more communications from at least one cell of the set in accordance with a schedule determined based on the system information, and the detected SSBs.

A terminal receives a synchronization signal block from a radio base station and calculates a quasi co-location associated with the synchronization signal block. The terminal applies a different calculation method of the quasi co-location according to the number of synchronization signal blocks included in a slot.

A method performed by a network entity is provided. The method comprises obtaining information indicating uplink, UL, and downlink, DL, time periods in the packet-based fronthaul network occupied by Time-Division Duplex, TDD, radio transmissions transmitted and/or received by the one or more second fronthaul network units over its radio interface. The method further comprises scheduling packet-based synchronization messages between at least the one or more first fronthaul network units and the one or more second fronthaul network units over the packet-based fronthaul network based on the obtained information. A network entity is also provided, as well as, computer programs and carriers.

A measurement method including determining, by a terminal device, a first adjustment parameter of a to-be-measured neighboring cell, determining, based on the first adjustment parameter, a first synchronization signal block-based measurement timing configuration (SMTC) window corresponding to the to-be-measured neighboring cell, and measuring the to-be-measured neighboring cell based on the first SMTC window.

A wireless audio service automatic resetting method and a wireless audio system are proposed. In the wireless audio service automatic resetting method and the wireless audio system thereof that are for a slave device, the slave device requests and receives latest audio service group information from a master device by connecting to a wireless network, and performs a corresponding operation by determining whether to recover to an in-service state on the basis of the latest audio service group information. Accordingly, the slave device may be conveniently recovered to the in-service state again without user's input, thereby receiving provision of a desired audio service.

Embodiments of this application provide a configuration information obtaining method and an apparatus, which may be applied to a scenario in which a terminal device obtains an RNTI. The terminal device may be in RRC inactive mode. The method may include: obtaining a cell identifier, and obtaining first configuration information based on the cell identifier, where there is a correspondence between the cell identifier and the first configuration information, and the first configuration information is used to configure an RNTI; and performing one or more of the following operations based on the first configuration information: receiving downlink control information, receiving downlink data, sending uplink control information, or sending uplink data.

A computer implemented system is provided for improving performance of transmission in real-time or near real-time applications from at least one transmitter unit to at least one receiver unit. The system includes an intelligent data connection manager utility that generates or accesses performance data for two or more data connections associated with the two or more communication networks, and based on the current performance data determining current network transmission characteristics associated the two or more data connections, and bonds the two or more data connections based on: a predetermined system latency requirement; and dynamically allocating different functions associated with data transmission between the two or more data connections based on their respective current network transmission characteristics. The data connection manager utility then manages dynamically the transmission of relatively large data sets across the two or more bonded or aggregated data connections in a way that meets the system latency requirement and improves performance in regards to other network performance criteria (including data transfer rate, errors, and/or packet loss). Related computer implemented methods are also provided.