An apparatus, method, and computer-readable recording medium perform client optimized onboarding in a wireless network. A network controller of a gateway device determines a first received signal strength indicator (RSSI) of a new client device, receives a second RSSI of the new client device from each of one or more wireless extenders, and determines a strongest RSSI among the determined first RSSI and the received second RSSI from each of the one or more wireless extenders. The network controller of the gateway device receives an onboarding request with respect to any one or the gateway device and the one or more wireless extenders, and sends a command to proceed with an onboarding operation of the new client device to any one of the gateway device and the one or more wireless extenders having the strongest RSSI from the new client device.

An apparatus, method, and computer-readable recording medium perform client optimized onboarding in a wireless network. A network controller of a gateway device determines a first received signal strength indicator (RSSI) of a new client device, receives a second RSSI of the new client device from each of one or more wireless extenders, and determines a strongest RSSI among the determined first RSSI and the received second RSSI from each of the one or more wireless extenders. The network controller of the gateway device receives an onboarding request with respect to any one or the gateway device and the one or more wireless extenders, and sends a command to proceed with an onboarding operation of the new client device to any one of the gateway device and the one or more wireless extenders having the strongest RSSI from the new client device.

To provide a low latency near RT RIC, some embodiments separate the RIC's functions into several different components that operate on different machines (e.g., execute on VMs or Pods) operating on the same host computer or different host computers. Some embodiments also provide high speed interfaces between these machines. Some or all of these interfaces operate in non-blocking, lockless manner in order to ensure that critical near RT RIC operations (e.g., datapath processes) are not delayed due to multiple requests causing one or more components to stall. In addition, each of these RIC components also has an internal architecture that is designed to operate in a non-blocking manner so that no one process of a component can block the operation of another process of the component. All of these low latency features allow the near RT RIC to serve as a high speed IO between the E2 nodes and the xApps.

To provide a low latency near RT RIC, some embodiments separate the RIC's functions into several different components that operate on different machines (e.g., execute on VMs or Pods) operating on the same host computer or different host computers. Some embodiments also provide high speed interfaces between these machines. Some or all of these interfaces operate in non-blocking, lockless manner in order to ensure that critical near RT RIC operations (e.g., datapath processes) are not delayed due to multiple requests causing one or more components to stall. In addition, each of these RIC components also has an internal architecture that is designed to operate in a non-blocking manner so that no one process of a component can block the operation of another process of the component. All of these low latency features allow the near RT RIC to serve as a high speed IO between the E2 nodes and the xApps.

Technologies directed to access point (AP) classification and selection to minimize a number of disconnect messages and achieve better throughput and reduce latency when a device is presented with multiple basic service set identifiers (BSSIDs) for AP selection are described. One method receives disconnect metrics from wireless devices, the disconnect metrics including a reason code associated with a disconnect message and a BSSID and an Organizationally Unique Identifier (OUI) associated with an AP. The method identifies a set of APs using a reason code for a load balancing or band steering operation by clustering the disconnect metrics. The method receives a query with a first BSSID and a first OUI associated with a first AP and determines that the first AP is part of the set of APs using the reason code. The method sends a response with the reason code being used for load balancing or band steering operation.

Technologies directed to access point (AP) classification and selection to minimize a number of disconnect messages and achieve better throughput and reduce latency when a device is presented with multiple basic service set identifiers (BSSIDs) for AP selection are described. One method receives disconnect metrics from wireless devices, the disconnect metrics including a reason code associated with a disconnect message and a BSSID and an Organizationally Unique Identifier (OUI) associated with an AP. The method identifies a set of APs using a reason code for a load balancing or band steering operation by clustering the disconnect metrics. The method receives a query with a first BSSID and a first OUI associated with a first AP and determines that the first AP is part of the set of APs using the reason code. The method sends a response with the reason code being used for load balancing or band steering operation.

In some examples, a headless device that is without an available user interface and that is to be provisioned for access to a network receives information relating to provisioning of the headless device from a network node. The headless device sends, to a mediator device with a user interface, at least a portion of the received information. The headless device receives, from the mediator device, information to proceed with the provisioning of the headless device.

Certain aspects of the present disclosure provide techniques for system acquisition in sidelink relay scenarios. An example method for adaptive paging by a relay node generally includes connecting, via a sidelink, to a remote user equipment (UE) while the relay node is also connected to a network entity, receiving, from the network entity, system information block (SIB) information, and sending the SIB information to at least the remote UE.

This application provides a communication method, an access network device, a terminal device, and a core network device. In a process in which the terminal device is handed over from a first access network device to a second access network device, the second access network device learns of first service progress of the first access network device based on a first sequence number of a data packet forwarded by the first access network device, without introducing additional progress exchange information between the two access network devices.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may establish a cellular connection with a base station associated with a cellular radio network. The UE may receive an access policy of the cellular radio network identifying an access preference rule for the UE to adopt for connections to a core network function of the cellular radio network, the access preference rule indicating for the UE to preferentially connect to the core network function via a non-cellular radio network. The UE may determine that a gateway between the non-cellular radio network and the core network function of the cellular radio network is not configured. The UE may determine that a gateway selection policy of the cellular radio network is not configured. The UE may establish a connection to a legacy core network function of a legacy cellular radio network via a legacy gateway.