Methods, systems, and apparatus' for optimizing network performance are described herein. A Cloud-Server may optimize one or more mesh networks of a plurality of 802.11 access points (APs) and stations (STA) connected to the APs. The Cloud-Server may work with a client steering daemon (CSD) miming on each AP. The Cloud-Server may operate in a location that is remote to the AP(s). The Cloud-Server may collect, store, and process network and client related data from one or more CSDs. The processing may include measuring network (e.g., premises) and client (e.g., STA) performance as well as analyzing (e.g., machine learning, etc.) to determine network parameters that will optimize network performance The Cloud-Server may then apply these network parameters to the relevant CSDs in order to improve per client and per network performance.

Provided are a method for adjusting a network camping policy of a terminal, a terminal, and a non-transitory computer-readable storage medium. In the method, the first terminal receives first network state information sent by at least one second terminal. The first network state information indicates whether a cell accessed by the second terminal within a preset time period is a cell of network anomaly. The first terminal adjusts a network camping policy of the first terminal, according to the first network state information and cell measurement information of candidate cells of the first terminal.

Embodiments of the present disclosure relate to multi-path operation. According to embodiments of the present disclosure, a measurement report is transmitted to a base station on a first path between the UE and the base station, wherein the measurement report indicates channel quality information on one or more potential paths between the UE and the base station. A path addition command is then received from the base station, wherein the path addition command indicates the UE to add a path from one or more potential paths as a second path. The second path between the UE and the base station is then established based on the path addition command.

A cell reselection method is a method that allows a user equipment to perform cell reselection of reselecting a cell to be used as a serving cell. The cell reselection method includes: transitioning from an RRC connected state to an RRC inactive state when a message is received from a network, the message including a configuration of a RAN notification area in which paging for the user equipment is performed; and after the transitioning to the RRC inactive state, selecting, among cells included in the RAN notification area, a redistribution target configured with a highest priority in the cell reselection, based on the RAN notification area configured according to the message and a redistribution parameter broadcast from the network.

This disclosure provides systems, methods, and apparatuses for dynamically changing a primary communication link on which wireless devices contend for access to a shared wireless medium. An access point (AP) may monitor the channel conditions on a primary link and one or more secondary links of a multi-link environment, and may signal a change in the primary link (such as to one of the secondary links) when one or more conditions are satisfied. The AP may signal the change to one or more wireless stations (STAs) in its Basic Service Set (BSS). In some aspects, the AP may signal the change in primary link via beacon frames broadcast periodically at Target Beacon Transmission Times (TBTTs). In some other aspects, the AP may signal the change in primary link via unicast management or control frames targeted at STAs that may not receive one or more beacons broadcast by the AP.

Provided are a method for steering traffic performed by a terminal in a wireless communication system, and the terminal using the method. The method comprises: receiving a traffic steering indicator from a first network; evaluating a traffic steering condition; and if the traffic steering condition is satisfied, operating in a first operation mode or a second operation mode indicated by the traffic steering indicator, wherein the first operation mode is an operation mode in which the terminal is capable of performing, by itself, traffic steering for moving traffic from the first network to a second network, and the second operation mode is an operation mode for reporting the evaluation result of the traffic steering condition to the first network.

The disclosure provides a packet offloading method, a mobile terminal, and a storage medium, the method comprising: detecting the link quality of a first Wi-Fi data link, detecting the link quality of a second Wi-Fi data link, and detecting the link quality of a mobile data link; based on the link quality of the first Wi-Fi data link, the link quality of the second Wi-Fi data link, and the link quality of the mobile data link, determining a packet allocation ratio between the first Wi-Fi data link, the second Wi-Fi data link, and the mobile data link; and transmitting packets to be transmitted over the first Wi-Fi data link, the second Wi-Fi data link, and the mobile data link according to the packet allocation ratio.

Systems herein allow an administrator to efficiently enroll computing devices into a mobile device management system, even when those computing devices are offline and not connected to the system. A management server can include a console that allows the administrator to enroll an offline computing device by selecting an offline enrollment option on a registration record. This option can cause the management server to create a device record, indicating the computing device is enrolled. The management server can also create and save a provisioning file onto a storage device, such as a USB drive. Assets, such as graphics and applications, specified by the device record are also saved onto the storage device. The storage device can be physically connected to the computing device, at which point the provisioning file guides automatic installation of the assets and implementation of device settings and compliance rules specified by the device record.

An architecture for facilitating smart physical cell identity (PCI) configuration for aerial network equipment that can used in terrestrial 4G and/or 5G LTE wireless networking paradigms. A method can comprise: receiving, from core network equipment, an instruction to travel from a first geographic location to a second geographic location, wherein the second geographic location has been determined, by the core network equipment, as representing a hotspot location; traveling from the first geographic location to the hotspot location; based on crossing a boundary associated with the hotspot location, initiating execution of a user equipment relay process that transitions the aerial user equipment from being user equipment to being aerial network equipment; and transmitting to the core network equipment that the user equipment relay process has been successfully initiated.

Methods, systems, and apparatus' for optimizing network performance are described herein. A Cloud-Server may optimize one or more mesh networks of a plurality of 802.11 access points (APs) and stations (STA) connected to the APs. The Cloud-Server may work with a client steering daemon (CSD) running on each AP. The Cloud-Server may operate in a location that is remote to the AP(s). The Cloud-Server may collect, store, and process network and client related data from one or more CSDs. The processing may include measuring network (e.g., premises) and client (e.g., STA) performance as well as analyzing (e.g., machine learning, etc.) to determine network parameters that will optimize network performance The Cloud-Server may then apply these network parameters to the relevant CSDs in order to improve per client and per network performance.