A base station receives, from an access and mobility management function (AMF), core network assistance information to assist radio access network (RAN) paging. The core network assistance information indicates that first paging occasions are conflicted with second paging occasions for a wireless device. Based on the core network assistance information a RAN paging adjustment of the first paging occasion is determined. A radio resource control (RRC) message is sent to the wireless device. The RRC message is for a transition the wireless device from an RRC connected state to an RRC inactive state. The RRC message comprises a parameter indicating the RAN paging adjustment. A RAN paging message based on the RAN paging adjustment is sent to the wireless device. A second RRC message to request a connection resuming with the wireless device is received from the wireless device.

Methods and apparatus for controlling device use of available networks, e.g., cellular and WiFi, are described. End devices report key performance indicator and resource utilization information, e.g., on a per application basis, to a configuration server. The configuration server determines, based on the received information, e.g., using machine learning and/or artificial intelligence, sets of configuration profiles, each configuration profile including one or more set of applications for which an end device should use a particular network. An exemplary configuration profile may identify a first set of applications for which a first network is to be used, e.g., a cellular network such as a P-LTE network, and a second set of applications for which a second network, e.g. a WiFi network, is to be used. The configuration server selects a configuration profile that is best suited for a particular end device and communicates that selected profile to the end device.

Methods, apparatus, systems and machine readable storage media of a multi-access edge computing (MEC) component operating in a multi-access management services (MAMS) framework are described. In an example, traffic on multi-radio links between a user equipment (UE) and a network is observed. Based on the observing, the traffic is managed by transmitting messages of a traffic management application programming interface (API) over a dedicated reference point.

The disclosed technology is directed towards load balancing in an adaptive and automated way for wireless mobility networks to improve the overall harmonic-average UE throughput within each controlled group of cells (e.g., different frequency carriers serving a sector of a base station). A load balancer (e.g., analytics component) obtains various device traffic data including throughput data for cells of a group. Pairs of cells in a group (sharing a site and face) can be selected based on satisfying various criteria, with estimated throughput gain achieved by changing the handoff rates between the cell pairs. The technology iteratively repeats the overall process, driving a system to an optimal equilibrium.

The disclosure relates to a 5th generation (5G) or pre-5G communication system for supporting a higher data transmission rate than a 4th generation (4G) communication system such as long term evolution (LTE). A method performed by a near-real time (RT) radio access network (RAN) intelligent controller (RIC) is provided. The method includes the steps of generating an RIC control message, and transmitting the RIC control message to an E2 node, wherein the RIC control message includes an information element (IE) for indicating a radio resource control (RRC) message type.

Some embodiments provide a method for performing radio access network (RAN) functions in a cloud at a user-level tracing application that executes on a machine deployed on a host computer in the cloud. The method receives data, via a RAN intelligent controller (RIC), from a RAN component. The method uses the received data to generate information related to traffic performance for at least one user. The method provides the generated information to the RIC.

The present invention relates to a method for offloading traffic by means of wireless LAN in a mobile communications system and apparatus therefor, and more particularly to a method for a terminal to offload traffic at a bearer level, and to a base station communicating with the terminal. The method for a terminal to offload traffic according to the present invention includes the steps of: while performing a data communication with a base station through a bearer of a first communications network, receiving from the base station an offloading command for offloading a part of traffic to a second communications network; transmitting a report of the offloading to the base station in response to the offloading command; and performing a data communication of the partial traffic with an accessible AP through a bearer of the second communications network without releasing the bearer of the first communications network.

A data packet transmission method—that includes: obtaining, by a terminal, N application programs that are running; and if the N application programs include an application program including a low-latency service; determining whether an unlicensed frequency band is in a congestion state; and instructing a network device to schedule a data packet of the terminal to a licensed frequency band for transmission when the unlicensed frequency band is in a congestion state. When determining that the N running application programs include the application program including the low-latency service, the terminal may instruct the network device to schedule the data packet of the terminal to the licensed frequency band for transmission, so as to transmit a data packet of the low-latency service by using the licensed frequency band. Resources in the licensed frequency band are centrally scheduled by the network device, instead of being used through contention.

A method for interfacing an information technology device with a gateway includes (1) receiving, at the gateway, first downlink data, and (2) steering the first downlink data from the gateway to a first information technology (IT) device via at least one of a first plurality of parallel data communication links between the first IT device and the gateway, according to a first steering policy.

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.