Described in the present disclosure are system and method embodiments for 5G and WLAN private network convergence to improve Quality of service (QoS) and Quality of experience (QoE) by switching, steering or splitting the traffic using a cognitive layer. The Cognitive layer may sense signal conditions and learn user preferences for traffic allocation between available Wi-Fi and 5G networks. In embodiments, the cognitive layer may comprise an Artificial Intelligence (AI) or Machine Learning (ML) module, signal conditions sensor, and user QoS/QoE aware schedulers. A cloud-based service controller may be incorporated to make decisions on user QoS and QoE allocation based on the cognitive layer input. Implementation of the network convergence embodiments may improve QoS/QoE.

A gateway communication resource provides access to a remote network over a communication link. For example, a communication management resource (such as in a subscriber domain) receives log information associated with the gateway communication resource. The log information indicates an operational status of the gateway communication resource. The communication management resource also receives performance threshold information in which to analyze performance of the communication resource. Via application of the performance threshold information to the log information, the communication management resource generates a performance report indicative of a performance status of the gateway communication resource communicating over the communication link.

A method and system for controlling the use of dormant capacity for distributing data includes communicating data as part of a regular traffic load through a network having an overall network capacity, determining a dormant capacity of the network based on regular network traffic load, delivering content to a plurality of devices through the network, receiving the data at the plurality of devices, based on receiving the data, measuring an efficiency metric at each of the plurality of devices, communicating the efficiency metric of the devices to a service provider, receiving the efficiency metric at the service provider from the devices, receiving a resource usage report from the network, determining a target throughput for each of the plurality of devices based on the resource usage report and communicating second data to the plurality of devices from a content delivery service based on the target throughput using the dormant capacity.

Techniques described herein improve direct communication channel reliability in a vehicle-to-everything (V2X) communication. The techniques include a (wireless communication) device that uses a first licensed band to perform a cellular network communication through a first interface (e.g., Uu), and further uses a shared spectrum to perform a V2X communication through a direct communication channel interface. The device then monitors and compares a bandwidth requirement of the V2X communication with a bandwidth of the shared spectrum. In response to the bandwidth that is less than the bandwidth requirement, the device selects a second licensed band that includes a bandwidth that is at least equal to the bandwidth requirement. Further, the selected second licensed band is different from the first licensed band to avoid channel interference. In other embodiments, the device uses the licensed band to directly establish the V2X communication.

The present disclosure relates to a communication method and system for converging a 5.sup.th-Generation (5G) communication system for supporting higher data rates beyond a 4.sup.th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. A method for controlling a terminal in a base station of a mobile communication system, according to an embodiment of the present application, comprises the steps of: selecting at least one candidate terminal for offloading; obtaining information on a neighbor cell of at least one of the candidate terminals; obtaining throughput improvement information according to offloading on the basis of information on the candidate terminal and load information of the neighbor cell of the candidate terminal; obtaining information on a target cell corresponding to the candidate terminal on the basis of the throughput improvement information; selecting a target terminal to be offloaded from the candidate terminals on the basis of the throughput improvement information corresponding to the target cell; and transmitting, to the target terminal, a message instructing offloading to the target cell corresponding to the target terminal.

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.

Systems, methods, and computer software are disclosed for providing an Open Radio Access Network (RAN) networking infrastructure. In one embodiment a method is disclosed, comprising: providing real-time OpenRAN controller responsible for radio connection management, mobility management, QoS management, edge services, and interference management for the quality of end user experience; and providing a non-real-time controller in communication with the real-time OpenRAN controller, the non-real-time controller providing functionality such as configuration management, device management, fault management, performance management, and lifecycle management for all network elements in a network.

A data router serves User Equipment (UEs) over network connections to network slices. The data router receives a container configuration and a connection configuration from a wireless communication network. The data router exchanges user data with the UEs. The data router executes data applications in operating system containers based on the container configuration. The data applications exchange the user data with the network slices over the network connections based on the connection configuration.

A complex control instruction chains in a blockchain for a specific task for controlling devices to be managed in a simple manner is provided, which permit a prescribed validity to be assigned for a specific task of a blockchain-based device control, the validity being defined by the life cycle (e.g. the period of use) of a device, for example.

Disclosed are a method (1) of and a management entity (23) for optimizing a radio performance of a wireless network (2). The wireless network (2) comprises a plurality (C) of communication channels and a plurality (N) of configurable radio access entities (21). The method (1) comprises determining (11), by a respective configurable radio access entity (21, i) of the plurality of configurable radio access entities (21), a respective set of receivable radio access entities (21, 22, j) in a particular communication channel of the plurality of communication channels. The method (1) further comprises collecting (12), by a management entity (23), the respective set of the receivable radio access entities (21, 22, j) determined by the respective configurable radio access entity (21, i) of the plurality of configurable radio access entities (21, i). The method (1) further comprises optimizing (13), by the management entity (23), the radio performance of the wireless network (2) in accordance with the respective set of the receivable radio access entities (21, 22, j) collected from the plurality of configurable radio access entities (21, i). The resulting channel allocation is quickly obtainable, straightforward to understand, and therefore enables users with even a little radio communications background to quickly and safely carry out a professional frequency optimization.