A network management function of a relay network may identify relay node support of multi-mobile terminal (MT) operation, and may coordinate configuration of multiple backhaul links supported by the relay node via the multi-MT functionality of the relay node. In some cases, a relay node may transmit MT capabilities to the management function over a first established backhaul link, and the management function may configure a second backhaul link using a second MT function of the relay node. In other cases, the relay node may autonomously establish multi-MT connectivity based on preconfigured parent-selection policies, and the network management function may identify the relay node is dual-connected to the network management function. In either case, the network management function may configure backhaul routes (e.g., backhaul links) and resource configuration across the redundant topology.

A communication control apparatus includes: an acquisition section (231) that acquires information concerning a service to be received, using a communication system (1), by a communication apparatus connected to the communication system (1) that includes a relay base station (30) to which the communication apparatus is connectable and a donor base station (20) which provides the relay base station (30) with a wireless backhaul line; and a determination section (232) that determines a path through which data exchanged between the communication apparatus and the donor base station (20) passes on a basis of the information concerning the service.

A communication control apparatus includes: an acquisition section (231) that acquires information concerning a service to be received, using a communication system (1), by a communication apparatus connected to the communication system (1) that includes a relay base station (30) to which the communication apparatus is connectable and a donor base station (20) which provides the relay base station (30) with a wireless backhaul line; and a determination section (232) that determines a path through which data exchanged between the communication apparatus and the donor base station (20) passes on a basis of the information concerning the service.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, an integrated access and backhaul (IAB) node may determine a cell configuration of a distributed unit (DU) of the IAB node. The cell configuration may be associated with a second IAB donor. The DU may be one of a set of DUs of the IAB node. The IAB node may have a first signaling connection to a central unit (CU) of a first IAB donor. The IAB node may provide the cell configuration associated with the second TAB donor. Numerous other aspects are provided.

A cloud radio access network (C-RAN) includes a plurality of remote units (RUs), each with a wireless transceiver to exchange RF signals with at least one UE. The C-RAN also includes a central controller communicatively coupled to the plurality of RUs via a fronthaul comprising one or more ETHERNET switches. The central controller is communicatively coupled to an activation server via a backhaul network. The central controller also includes at least one processor configured to, following initial power up, establish a connection to the activation server indicated by activation server information pre-configured on the central controller. The at least one processor is also configured to receive a commissioning package, which includes commissioning information, from the activation server. The at least one processor is also configured to configure the central controller based on the commissioning information.

There is provided a method and apparatus for data transmission using shared radio bearer in order to simplify the operation of RAN access node by reducing signalling overhead related to mobility and simplifying per UE RBs setup/release operation. Using the shared radio bearer, UE mobility operation becomes transparent to access node (e.g. edge cell) and to UE. There is also provided a method and apparatus for simplifying the operation of UE for RBs setup/release and to make the Layer 2 (L2) operation independent from mobility (e.g. independent from handover).

A communication system capable of dynamically changing an MME to serve in call processing in accordance with the load condition of the MMEs and the like is provided. A communication system of the present invention includes: communication control apparatuses (10) to (12); and a node apparatus (20) that executes call processing relating to a communication terminal with the communication control apparatuses (10) to (12). The communication control apparatuses (10) to (12) form a context sharing group that shares subscriber data of the communication terminal. The node apparatus (20) selects a first communication control apparatus in the context sharing group, and transmits a call processing message to the first communication control apparatus. The first communication control apparatus executes the call processing using the subscriber data shared in the context sharing group.

A network device can receive a request from an application server for availability information associated with a response period in which a user equipment is responsive to communications. The network device can send a status query related to the user equipment to a radio access network controller device that processes signals between the user equipment and a mobile network core device. The network device can receive the availability information from the radio access network controller device and transmit a notification message to the application server that indicates the response period.

A RAN node apparatus (1) sends to, an AMF (3) in a core network, slice support information indicating a network slice supported by another RAN node (2) that can be used as a secondary node in dual connectivity in which the RAN node apparatus (1) acts as a master node. This can contribute, for example, to allowing the AMF to determine a network slice allowed to a UE, while taking into account a network slice supported by a secondary node of dual connectivity.

The present disclosure relates to establishment of communication between a computing devices and a gateway via a Mobility Management Entity (MME) and a base station, wherein a communication channel is initially established between the computing device and the base station, based on which the MME performs authentication of the computing device and also creates an Evolved Packet System (EPS) bearer between the computing device and the gateway.