A system, method, and computer-readable medium are disclosed for performing a connectivity handover operation. The connectivity handover operation includes: identifying a Wireless Wide Area Network (WWAN) link, the WWAN link having an associated WWAN location quality identifier; identifying a Wireless Local Area Network (WLAN) link, the WLAN link having an associated WLAN location quality identifier; monitoring the associated WWAN location quality identifier and the associated WLAN location quality indicator; determining whether the WWAN link should be activated based upon the associated WLAN location quality identifier; and, performing the connectivity handover operation based upon the determining.

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.

A method and system for controlling uplink communication from a user equipment device (UE) that has at least two co-existing air-interface connections including a first air-interface connection with a first access node and a second air-interface connection with a second access node. An example method includes comparing a level of uplink backhaul congestion of the first access node with a level of uplink backhaul congestion of the second access node and, based at least on the comparing, configuring an uplink split ratio defining a distribution of uplink user-plane data flow of the UE between at least the first air-interface connection and the second air-interface connection. In an example implementation, this could involve configuring one of the air-interface connections as a primary uplink path to which the UE restricts its uplink communication unless and until a trigger occurs for transitioning the UE to operate in an split-uplink mode.

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.

The present application is related to a method performed by a user equipment (UE). The method includes: obtaining a power based at least in part on path-loss of a link between the UE and a base unit; obtaining another power based at least in part on path-loss of a sidelink between the UE and another UE; selecting one of the power and the abovementioned another power as transmission power; and transmitting data on the sidelink using the transmission power.

A first device in a communication network receives from at least one second device in the communication network, a first request for acquiring a token, the token being permission for communicating with a third device. Based on the first request, a device from the at least one second device and the first device as a communication device is selected for providing a communication service to the third device in the communication network; and the token is transmitted to the communication device. The communication device receives the token for communicating with the third device. Other devices receive key information associated with communication of the third device from the first device, and monitor data associated with the communication of the third device.

Systems and methods described herein provide an intelligent MEC resource scheduling service. A network device in a MEC network stores, in a memory, threshold values indicating overload conditions for resource usage by a first MEC cluster; monitors resource usage in the first MEC cluster; determines, based on the monitoring, when one of the threshold values is reached; identifies available resources in a second MEC cluster; and re-directs, based on the identifying, at least some of the resource usage from the first MEC cluster to the second MEC cluster.

The present disclosure provides a method for automatic offloading of a user device into wireless network (Wi-Fi) using an ANDSF application. The method includes a first step to configure available wireless network (Wi-Fi) at the user device. The method includes a second step to validate wireless network (Wi-Fi) at the user device. The method includes a third step to offload the user device into wireless network (Wi-Fi). In addition, wireless network (Wi-Fi) is configured into ANDSF policy. Further, ANDSF policy is configured in ANDSF server. Furthermore, ANDSF server is associated with the ANDSF application. Moreover, wireless network (Wi-Fi) is validated using the ANDSF application. Also, the ANDSF application validates configured wireless network (Wi-Fi) based on Quality of Experience (QOE) parameters. Also, the user device is offloaded using the ANDSF application.

Methods for data downloading and a related terminal device are provided, which include, upon receiving a downloading instruction input by a user, determining a target downloading task and determining communication protocols currently supported by the terminal device. The target downloading task can be divided into a plurality of subtasks based on preset ways. At least two communication protocols from the communication protocols currently supported by the terminal device are selected as target communication protocols. Downloading of the plurality of subtasks is based on the target communication protocols.

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.