Network nodes, methods and computer program products are disclosed. The network node is for a wireless telecommunications network and comprises: processing logic operable to execute an application which establishes a data session for transmission of data packets between the network node and another network node; a first radio interface operable to support transmission of data packets with the another network node using a first radio access technology in accordance with any of a plurality of different data transport protocols; a second radio interface operable to support transmission of data packets with the another network node using a second radio access technology in accordance with any of a plurality of different data transport protocols; and a controller operable to select which radio interface and data transport protocol to use for transmission of the data packets of the data session between the network node and the another network node. In this way, the network node is able to transmit data packets between the network node and the other network node for the data session using any of the different radio interfaces and any of the different data transport protocols. This provides for the flexibility to select the radio interfaces and data transport protocols appropriate to the network conditions in order to improve the communication performance and alleviate any performance impacts caused by the network.

A network selection control method is a method for selecting, from a E-UTRAN and a WLAN, an access network in which a traffic of a UE 100 is transmitted and received. The network selection control method comprises the steps of: transmitting, by a cell #1 in the E-UTRAN, offload control information to a UE 100-1 that exists in the cell #1, the offload control information being for requesting switching of an access network in which the traffic of the UE 100-1 is transmitted and received, to the WLAN; and transmitting, by a cell #2 neighboring the cell #1 in the E-UTRAN, to a UE 100-2 that exists in the cell #2, neighboring cell offload information indicating that the offload control information is transmitted in the cell #1.

The present invention discloses a method for accessing s network system, including the following steps: receiving, by a first network device of a first network system, a measurement report of a second network system sent by a user equipment of the first network system; determining, by the first network device, a second network device in the second network system according to the measurement report; and sending, by the first network device, a bearer setup request to the second network device, for enabling the second network device to set up a connection with the user equipment. The present invention, by realizing aggregation between a two network systems, may dynamically schedule the resources of the two network systems according to loads of the two network systems, thereby provides load balancing with extremely high efficiency, and is capable of increase the peak data rate of the user effectively and remarkably.

A portable communication device includes a touch screen display; first communication circuitry configured to support a long term evolution (LTE) communication; second communication circuitry configured to support a new radio (NR) communication; a memory storing operator information indicating an operator of a mobile network and operator policy information; and at least one processor configured to receive, from an LTE base station corresponding to the mobile network via the first communication circuitry, a system information block (SIB) and a non-access stratum (NAS) message, determine, based on the SIB and the NAS message, whether dual connectivity of the LTE communication and the NR communication is available for the portable communication device, based on the operator information, the operator policy information and determining that the dual connectivity is available for the portable communication device, select an indicator from a first indicator and a second indicator, the first indicator indicating that the portable communication device is connected with the mobile network via the LTE communication, the second indicator indicating that the NR communication is available for the portable communication device to connect with the mobile network, and display the selected indicator via the touch screen display.

A primary access node adds a secondary access node to deliver wireless communication service to a User Equipment (UE). The primary access node comprises baseband circuitry and a radio. The radio wirelessly receives a measurement report from the UE that characterizes a radio metric for the secondary access node. The baseband circuitry determines insertion loss for the secondary access node and an add threshold for the secondary access node based on the insertion loss. The baseband circuitry determines an add value for the secondary access node based on the radio metric. When the add value exceeds the add threshold, the baseband circuitry transfers network signaling to the secondary access node to serve the UE and transfers user signaling to the UE over the radio. The UE attaches to the secondary access node and the secondary access node delivers the wireless communication service to the UE.

This disclosure describes systems, devices, and computer-implemented methods that facilitate the simultaneous transmission of subsets of user plane data to a telecommunications network via two or more uplink transmission paths. More specifically, a mobile device may detect user plane data within a buffer pool and in doing so, transmit a resource allocation request for the uplink transmission of the user plane data. In response, the mobile device may receive a set of control plane data associated with the uplink transmission via two or more uplink transmission paths. The mobile device may simultaneously transmit subsets of user plane data to the telecommunications network via multiple base station nodes, based at least in part on the control plane data.

A technique for enabling connection-oriented multipath transmission is disclosed. A computing unit (110) for executing a multipath application (102) enabling connection-oriented multipath transmission between a client application (106) and a server (108) comprises at least one processor and at least one memory, wherein the at least one memory contains instructions executable by the at least one processor such that the multipath application (102) is operable to receive a packet from the client application (106), the packet being destined for the server (108) and associated with a connection established between the client application (106) and the server (108) using a connection-oriented transport protocol, select an interface from a plurality of interfaces of the computing unit (110) for transmission of the packet to a multipath proxy (104) for delivery to the server (108), and transmit the packet to the multipath proxy (104) via the selected interface.

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.

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.

This disclosure describes systems, devices, and computer-implemented methods that facilitate the simultaneous transmission of subsets of user plane data to a telecommunications network via two or more uplink transmission paths. More specifically, a mobile device may detect user plane data within a buffer pool and in doing so, transmit a resource allocation request for the uplink transmission of the user plane data. In response, the mobile device may receive a set of control plane data associated with the uplink transmission via two or more uplink transmission paths. The mobile device may simultaneously transmit subsets of user plane data to the telecommunications network via multiple base station nodes, based at least in part on the control plane data.