Disclosed is method and an evolved NodeB (eNB) for use in a Long Term Evolution (LTE) network including establishing an X2 interface between the eNB and another eNB and communicating information between the eNB and the another eNB via the X2 interface.

A method and apparatus for transmitting a local home network identity (LHN ID) in a wireless communication system is provided. A first evolved NodeB (eNB) transmits an X2 Setup Request message including a LHN ID of the first eNB to a second eNB, and receives an X2 Setup Response message including a LHN ID of the second eNB from the second eNB. The first eNB may determine whether or not to trigger a secondary eNB (SeNB) addition procedure according to the LHN ID of the second eNB. When it is determined that the LHN ID of the second eNB is the same as the LHN ID of the first eNB, the first eNB may trigger the SeNB addition procedure.

A communications network is disclosed that includes one or more microwave backhaul nodes for routing communications between one or more near end mobile communications devices and one or more far end mobile communications devices. The communications network includes a central monitoring and control infrastructure, a remote monitoring and control infrastructure and/or a local monitoring and control infrastructure. The central monitoring and control infrastructure, the remote monitoring and control infrastructure and/or the local monitoring and control infrastructure can directly manage the one or more microwave backhaul nodes. Alternatively, the remote monitoring and control infrastructure and/or the local monitoring and control infrastructure can indirectly manage the one or more microwave backhaul nodes through the central monitoring and control infrastructure.

The present invention claims a TR069 protocol management method oriented to a WIA-PA network, where a traditional TR069 network management system architecture is improved to extend a TR069 protocol only oriented to Internet terminal device management in an initial design from the Internet to a WIA-PA wireless sensor network; a session connection interaction process between an ACS and a CPE is expanded to establish a session connection between the ACS and a WIA-PA network node; a virtual device mechanism is designed by taking a WIA-PA network gateway as the CPE to store a TR069 data model and proxy device information corresponding to a WIA-PA data model and implement the TR069 protocol to manage the WIA-PA network node in a manner as simple and transparent as that for an interaction between the ACS and the common CPE; a management data model mapping mechanism is designed to establish a correlation from the WIA-PA data model described in TR069 to a standard WIA-PA data model; and a protocol conversion interlace is designed to implement the conversion between a TR069 RPC method and a WIA-PA network management command frame. The TR069 protocol management method has a good reference value for the implementation of the M2M management of the whole network as well as the application and development of the TR069 protocol oriented to the wireless sensor network.

A method comprising: receiving at a source serving node (505) an identifier associated with a group of random access channel preambles for allocation by the source serving node (505), the group of random access channel preambles having been reserved at a serving node (503) from available random access channel preambles for the serving node (503); allocating at least one from the group of random access channel preambles, in response to determining a handover from the source serving node (505) to a target serving node (507); and transmitting (515) a message to the target serving node (507), the message comprising the at least one from the group of random access channel preambles.

A method comprising: receiving at a source serving node (505) an identifier associated with a group of random access channel preambles for allocation by the source serving node (505), the group of random access channel preambles having been reserved at a serving node (503) from available random access channel preambles for the serving node (503); allocating at least one from the group of random access channel preambles, in response to determining a handover from the source serving node (505) to a target serving node (507); and transmitting (515) a message to the target serving node (507), the message comprising the at least one from the group of random access channel preambles.

Embodiments of the present disclosure provide a method and system for implementing multi-user multiple-input multiple-output (MU-MIMO). The method includes: connecting two MU-MIMO-supported access points to form a virtual access point stack; setting a primary access point and a secondary access point in the virtual access point stack; performing access point configuration on the primary access point, and synchronizing the configuration of the primary access point to the secondary access point; and scheduling all antennas of the virtual access point stack by the primary access point. According to the embodiments of the present disclosure, wireless capacity is improved without consuming extra wireless spectrum resources.

A data transmission method and apparatus are disclosed. The method includes: determining, by a source base station of a terminal in a handover process, first data and a radio air interface protocol sequence number of a data unit used to carry the first data, where the first data includes data that is not acknowledged by a terminal for correct reception during data transmission between the source base station and the terminal. The method further includes sending, by the source base station, the first data and the radio air interface protocol sequence number to a target base station; where the core network connected to the target base station is different from the core network connected to the source base station.

A method of operating a first infrastructure equipment of a wireless communications network comprising a core network part, the first infrastructure equipment, a second infrastructure equipment acting as a backhaul relay node between the first infrastructure equipment and the core network part, and a downstream wireless communications device. The method comprising receiving from the second infrastructure equipment an indication of a first set of communications resources, allocating resource elements of the first set of communications resources for receiving first data for transmission to the core network part from the downstream wireless communications device, and receiving second data transmitted by the second infrastructure equipment on one or more resource elements within a second set of communications resources, the second set of communications resources different from the first set of communications resources.

A radio station (2) transmits configuration information (501) to a radio terminal (1). The configuration information (501) indicates, on a cell-by-cell basis, at least one specific cell on which the radio terminal (1) is allowed to perform at least one of data transmission and data reception on a radio bearer used for uplink transmission or downlink transmission or both via a common Packet Data Convergence Protocol (PDCP) layer (402). As a result, in a radio architecture that provides tight interworking of two different Radio Access Technologies (RATs), it is for example possible to allow an eNB to indicate, to a radio terminal (UE), a specific cell on which the UE should perform uplink transmission.