A network device receives location information for a user equipment device (UE), an application identifier (ID), and a latency requirement associated with a data session involving the UE. The network device retrieves from a database, based on the UE's location information, the application ID, and the latency requirement, Multi-Access Edge Computing (MEC) selection weight values associated with multiple MEC platforms. The network device selects a MEC platform, from among the multiple MEC platforms, based on the retrieved MEC selection weight values, and causes the data session to be established between the selected MEC platform and the UE.

A base station device may include a memory configured to store instructions and a processor configured to execute the instructions to obtain one or more radio signal quality parameter values associated with a user equipment (UE) device and determine a channel quality class associated with the UE device based on the obtained one or more radio signal quality parameter values using a machine learning model. The processor may be further configured to identify an application data stream associated with the UE device, select an application bandwidth for the application data stream based on the determined channel quality class, and send application data associated with the application data stream to the UE device based on the selected application bandwidth.

A managed Wi-Fi service network device can receive, from a cellular network device, an allowable throughput rate at which a user equipment is authorized to communicate via a managed Wi-Fi service network. Based on the allowable throughput rate, the managed Wi-Fi service network device can monitor a communication rate of the user equipment via the managed Wi-Fi service network. In response to the user equipment communicating via the managed Wi-Fi service network at a rate that exceeds the allowable throughput rate, the managed Wi-Fi service network device can facilitate reducing the communication rate of the user equipment. Also, a user equipment can receive from a cellular network device an allowable throughput rate at which the user equipment is authorized to communicate via the managed Wi-Fi service network. The UE can communicate via the managed Wi-Fi service network at a communication rate that does not exceed the allowable throughput rate.

Methods, systems, and devices for wireless communications are described. A first wireless device (e.g., user equipment (UE), base station) may determine a block fading pattern associated with a communication link between the first wireless device and a second wireless device, the block fading pattern including a pattern of fluctuating channel quality. The first wireless device may selectively adjust one or more communications parameters for communicating with the second wireless device over the communication link based on the determined block fading pattern. The first wireless device may then communicate with the second wireless device over the communication link based at least in part on the one or more adjusted communications parameters.

Concepts and technologies disclosed herein are directed to intelligent drone traffic management via a radio access network (“RAN”). As disclosed herein, a RAN node, such as an eNodeB, can receive, from a drone, a flight configuration. The flight configuration can include a drone ID and a drone route. The RAN node can determine whether capacity is available in an airspace associated with the RAN node. In response to determining that capacity is available in the airspace associated with the RAN node, the RAN node can add the drone ID to a queue of drones awaiting use of the airspace associated with the RAN node. When the drone ID is next in the queue of drones awaiting use of the airspace associated with the RAN node, the RAN node can instruct the drone to fly through at least a portion of the airspace in accordance with the drone route.

Communication between a client device and a host device using a first Radio Access Technology (RAT) may be configured. The host device communicates with a base station of a network using a second RAT, to provide services of the network to or from the client device. The communication between the host device and the base station distinguishes data traffic in accordance with a set of network traffic rules. Information relating to the set of network traffic rules is communicated from the host device to the client device. The communication between the client device and the host device using the first RAT is configured according to a set of client traffic rules that are based on the communicated information about the network traffic rules.

A network access method and a terminal relate to the communications field, where the method includes obtaining, by the terminal, a priority of a first network service, determining, by the terminal according to a relationship between a network service priority and a network service class, a network service class required for performing the first network service, where the relationship is stored in the terminal, obtaining, by the terminal, a network service class of a first network currently accessed by the terminal, accessing, by the terminal, a second network whose network service class is higher than the network service class of the first network when the network service class of the first network is lower than the network service class required for performing the first network service, and performing the first network service using the second network.

There is provided mechanisms for handling reporting of performance degradation from wireless devices in a communications system. A method is performed by a network node in the communications system. The method includes determining a configuration for real time reporting of events from wireless devices in idle mode. The events pertain to performance degradation experienced by the wireless devices when in idle mode. The configuration includes restrictions in terms of real time reporting of the events to the network node. The method includes providing information of the configuration to the wireless devices.

Some implementations of the disclosure relate to a backend server that is configured to perform operations including: determining one or more radio frequency (RF) gateways that are candidates for communicating with an end device over a RF link in a low-power wide-area network (LPWAN); obtaining, for each of the one or more RF gateways, a round trip time (RTT) of communications between the backend server and the RF gateway over a backhaul link; determining whether at least one of the one or more RTTs exceeds a threshold value; and when at least one of the one or more RTTs exceeds the threshold value, increasing a configured time interval between transmission of an uplink message by the end device and a downlink receive time slot in which the end device is configured to listen for a downlink message.

A terminal device includes an estimation unit and a distribution unit. The estimation unit estimates the radio transmission capacity of a second radio transmission path on the basis of a reception level of a radio signal from each of a first radio transmission path and the second radio transmission path. The second transmission path includes at least one radio repeater and is divided into two with the radio repeater disposed in between so that one side thereof towards the communication apparatus serves as a first radio section and the other side thereof opposite to the one side serves as a second radio section. The distribution unit distributes the data input thereto to the first radio transmission path and to the second radio transmission path on the basis of the radio transmission capacity of the first radio transmission path and the estimated radio transmission capacity of the second radio transmission path.