Embodiments of the present invention provide a frequency reuse method and a related apparatus. The method in the embodiments of the present invention includes: sending, by an access point, a first message to a station, where the first message carries indication information indicating that a basic service set is in a fractional frequency reuse mode; receiving, by the access point, a second message sent by the station, where the second message carries indication information indicating that the station supports the fractional frequency reuse mode; and communicating, by the access point, with the station in the fractional frequency reuse mode after the access point determines, according to the second message, that the station supports the fractional frequency reuse mode. In the embodiments of the present invention, frequency interference in a Wi-Fi network can be effectively reduced.

Embodiments of the present invention provide a frequency reuse method and a related apparatus. The method in the embodiments of the present invention includes: sending, by an access point, a first message to a station, where the first message carries indication information indicating that a basic service set is in a fractional frequency reuse mode; receiving, by the access point, a second message sent by the station, where the second message carries indication information indicating that the station supports the fractional frequency reuse mode; and communicating, by the access point, with the station in the fractional frequency reuse mode after the access point determines, according to the second message, that the station supports the fractional frequency reuse mode. In the embodiments of the present invention, frequency interference in a Wi-Fi network can be effectively reduced.

A network access method includes: learning, by a first RN, that a site type of a first communications site is an RN; and sending, by the first RN, first indication information to the first communications site, so that the first RN accesses the first communications site, where the first indication information carries information indicating that a site type of the first RN is an RN.

Aspects of the disclosure are directed toward intelligently selecting the operating parameters of wireless access points (WAPs) deployed in a wireless environment so as to minimize or at least reduce interference in that wireless environment. A WAP continually measures the characteristics of the wireless channels used in the wireless environment and obtains measurements of channel metrics for those channels. The WAP stores the channel metric measurements as a channel metric history and analyzes the channel metric history to determine correlations between the channel metric measurements and various timeframes. The WAP selects one or more of its operating parameters based on the channel metric history and the correlations identified. Operating parameters include the radio frequency band and channel to transmit on. A centralized control server may also receive, store, and analyze channel metric histories from multiple WAPs and issue instructions to those WAPs identifying values for their respective operating parameters.

Aspects of the disclosure are directed toward intelligently selecting the operating parameters of wireless access points (WAPs) deployed in a wireless environment so as to minimize or at least reduce interference in that wireless environment. A WAP continually measures the characteristics of the wireless channels used in the wireless environment and obtains measurements of channel metrics for those channels. The WAP stores the channel metric measurements as a channel metric history and analyzes the channel metric history to determine correlations between the channel metric measurements and various timeframes. The WAP selects one or more of its operating parameters based on the channel metric history and the correlations identified. Operating parameters include the radio frequency band and channel to transmit on. A centralized control server may also receive, store, and analyze channel metric histories from multiple WAPs and issue instructions to those WAPs identifying values for their respective operating parameters.

Baseband circuitry receives and processes measurement reports from multiple User Equipment (UEs) at multiple locations and responsively determines radio metric variances at the multiple locations. The baseband circuitry receives attachment signaling from a new UE, determines the location for the new UE, and determines a measurement time period for the new UE based on the radio metric variance at the location of the new UE. The baseband circuitry transfers the measurement time period to the new UE. The baseband circuitry receives and processes a measurement report from the new UE and determines to add a secondary access node based on a radio metric for the secondary access node in the new measurement report. The baseband circuitry transfers network signaling to the secondary access node to serve the new UE and transfers additional user signaling to new UE to attach to the secondary access node.

An electronic apparatus, method, and computer-readable medium implement smart channel selection to track client devices that connect with a LAN over time, store a historical number of client devices that connect with the LAN and a channel number on which the apparatus operated each connection with the client devices, and determine whether a number of probes/association requests on a current channel in the 5 GHz band on which the apparatus is operating is less than a predefined threshold value. When the number of probes/association requests on the current channel in the 5 GHz band on which the apparatus is operating is less than a predefined threshold value, smart channel selection is performed to select a new channel in the 5 GHz band, and the 5 GHz SSID of the apparatus is broadcasted on the new channel.

Methods by which User Plane (UP) management information is exchanged between an Application Function (AF) supporting one or more applications and a Slice Management Function (SMF) configured to manage traffic flows in a given slice of the network. The exchange of UP management information may be initiated from either the AF or the SMF. In the case of AF-initiated information exchange, the UP management information provided by the AF may comprise traffic requirements of applications supported by the AF. In the case of SMF-initiated information exchange, the UP management information provided by the SM may comprise operator policy information or events, and the AF may respond with information of traffic requirements of applications supported by the AF.

Methods by which User Plane (UP) management information is exchanged between an Application Function (AF) supporting one or more applications and a Slice Management Function (SMF) configured to manage traffic flows in a given slice of the network. The exchange of UP management information may be initiated from either the AF or the SMF. In the case of AF-initiated information exchange, the UP management information provided by the AF may comprise traffic requirements of applications supported by the AF. In the case of SMF-initiated information exchange, the UP management information provided by the SM may comprise operator policy information or events, and the AF may respond with information of traffic requirements of applications supported by the AF.

A central entity determines a physical cell identifier (PCI) change of an integrated access and backhaul (IAB) node from a first PCI to a second PCI and sends the second PCI to the IAB node. In response to receiving the second PCI from the central entity, the IAB node changes from using the first PCI to using the second PCI for the IAB node.