A method, device, and non-transitory computer-readable medium provide for scanning, by a device, a radio service area of a small cell radio access node to detect radio signals of one or more radio frequency (RF) bands, the radio signals including transmissions associated with one or more other small cell radio access nodes that are operating in a vicinity of the small cell radio access node, and the small radio access node being configured to alternately operate at multiple RF bands including the one or more RF bands; determining, by the device, a signal strength associated with each of the one or more RF bands; and dynamically optimizing, by device, operation of the small cell radio access node based on the signal strength associated with each of the one or more RF bands.

A communication method and apparatus are provided. The method includes: A control plane device obtains first information of a first terminal device, where the first information indicates a terminal device that has mutual trust with the first terminal device, and the terminal device that has mutual trust with the first terminal device includes a second terminal device. The control plane device sends a first message to a first user plane device, where the first message includes route configuration information, the route configuration information is used to configure a first transmission path, the first transmission path is used to forward data to a second terminal device via the first terminal device, and the first user plane device is configured to provide a user plane data forwarding service for the first terminal device.

Embodiments of this application provide a communication method, apparatus. One example method includes: a first data analytics network element receive a first request from a sec data analytics network element, wherein the first request carries an analytics type identifier and second model requirement information, and the first request requests information of a model that corresponds to the analytics type identifier and meets the second model requirement information. The second data analytics network element receives the information of the model from the first data analytics network element.

Embodiments of this application provide a communication method, apparatus, and system. In the method, after a first remote radio unit (RRU) determines that a link between the first RRU and a baseband unit (BBU) is in an abnormal state, the first RRU sends information about the first RRU and/or information about an optical module connected to the first RRU to at least one second RRU by using a power line communication (PLC) module in the first RRU. The first RRU is connected to the at least one second RRU by using a power line, and a PLC module is also disposed in the at least one second RRU.

Embodiments of this application provide a communication method, apparatus, and system. In the method, after a first remote radio unit (RRU) determines that a link between the first RRU and a baseband unit (BBU) is in an abnormal state, the first RRU sends information about the first RRU and/or information about an optical module connected to the first RRU to at least one second RRU by using a power line communication (PLC) module in the first RRU. The first RRU is connected to the at least one second RRU by using a power line, and a PLC module is also disposed in the at least one second RRU.

This application discloses a cell selection and reselection method, an apparatus, a terminal, and a readable storage medium. The method includes: measuring a first reference signal and/or a second reference signal; and choosing to camp on a first cell or a second cell based on a measurement result. The first reference signal is a single-frequency network SFN specific reference signal, the second reference signal is a cell/transmission reception point cell/TRP specific reference signal, the first cell is an SFN specific cell, and the second cell is a cell/TRP specific cell or TRP.

A wireless network extender device for use with a wireless access point device being connected to a wireless network, and being configured to transmit an onboarding communication on a current operating channel, said wireless network extender device comprising: a radio; a memory having instructions and country code data; and a processor configured to execute the instructions stored on said memory to cause said wireless network extender device to: receive the onboarding communication on the current operating channel; identify the determined maximum broadcasting power based on the onboarding communication and the country code data; and initiate the onboarding process with the wireless access point device at the determined maximum broadcasting power on the current operating channel.

A client device for use with a wireless network controller device, a connected wireless APD and a second wireless APD, the client device including: a memory; and a processor configured to execute instructions stored on the memory to cause the client device to: associate with the wireless network; and transmit an onboard new APD instruction to the wireless network controller device to cause the wireless network controller device to: transmit a restricted mode instruction to instruct the connected wireless APD and to instruct the connected wireless APD to transmit a beacon; receive a notification of the probe request; transmit the onboarding instruction to instruct the connected wireless APD; and transmit the primary mode instruction to instruct the connected wireless APD, wherein the onboarding instruction causes one of: the connected wireless APD to transmit the beacon; and the connected wireless APD to not transmit the beacon only on the assigned channel.

A system and method for managing interference between different enterprises operating over the same spectrum. The system includes central units of a host, a first enterprise and a second enterprise; a first interface for connecting the central unit of the host to the central unit of the first enterprise; and a second interface for connecting the central unit of the host to the second enterprise; wherein the central unit of the host is configured to: enable relaying of load information between the first and second enterprises to minimize interference between each enterprise when the first and second enterprises are operating in the same spectrum and an overlapping coverage region between cell sites; and arbitrate transmission requests from a respective enterprise based on information from service level agreements (SLAs) shared between the central unit at the host and the respective enterprise.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may determine a scaling factor for a UE measurement period based at least in part on the UE being associated with a non-terrestrial network (NTN). The UE may perform a measurement during a scaled UE measurement period based at least in part on the scaling factor and the UE measurement period. Numerous other aspects are described.