Abstract: Providing mobility support of UEs that are served by mobile relay base stations, by providing handover of a UE for data traffic only between two mobile relay base stations. Exchanging information between the source and target mobile relay stations of the concerned UE in handover, and/or the corresponding donor base stations if applicable. The handover is triggered by any of the following: based on UE's measurement report, the signal quality of a neighbor cell is better than the current serving cell; based on the measurement of the serving mobile relay base station, the signal quality of the link to the UE is worse than a certain threshold; or based on the measurement of the serving mobile relay base station, the signal quality of a neighbor cell is much better than the current donor base station.

Abstract: A buffer status reporting scheme for a terminal (10) wishing to transmit data simultaneously in multiple RATs of a wireless communication network, which enables the co-ordination of multiple base stations (12, 14) of different RATs (e.g. LTE eNB, UMTS base station, WiFi access point, etc.) with the assistance of the terminal (10) in order to achieve efficient radio resource scheduling for multi-RAT multi-flow aggregation in uplink. A radio bearer is configured for multi-RAT multi-flow aggregation by the network, and multiple logical channel IDs are assigned to this RB that may be associated with different RATs. Logical channels associated with a certain RAT (or a given set of RATs) may be grouped into one logical channel group for radio resource scheduling reason. The terminal (10) performs buffer status reporting, according to the configuration, on all involved RATs and sends reports/indications to one or more involved base stations (12.14).

Abstract: A method of implementing multiple radio access technologies, RATs, by a multi-RAT wireless communication network and a wireless communication apparatus. The multi-RAT wireless communication network transmits, to the wireless communication apparatus, a signal relating to a second RAT using a first RAT. The wireless communication apparatus uses a first radio communication module configured to support the first RAT to receive the signal, and activates a second radio communication module configured to support the second RAT from a power saving in order to perform a function. The first RAT generally has lower power consumption in use at the wireless communication apparatus than that of the second RAT.

Abstract: A buffer status reporting scheme for a terminal (10) wishing to transmit data simultaneously in multiple RATs of a wireless communication network, which enables the co-ordination of multiple base stations (12, 14) of different RATs (e.g. LTE eNB, UMTS base station, WiFi access point, etc.) with the assistance of the terminal (10) in order to achieve efficient radio resource scheduling for multi-RAT multi-flow aggregation in uplink. A radio bearer is configured for multi-RAT multi-flow aggregation by the network, and multiple logical channel IDs are assigned to this RB that may be associated with different RATs. Logical channels associated with a certain RAT (or a given set of RATs) may be grouped into one logical channel group for radio resource scheduling reason. The terminal (10) performs buffer status reporting, according to the configuration, on all involved RATs and sends reports/indications to one or more involved base stations (12.14).

Abstract: Providing mobility support of UEs that are served by mobile relay base stations, by providing handover of a UE for data traffic only between two mobile relay base stations. Exchanging information between the source and target mobile relay stations of the concerned UE in handover, and/or the corresponding donor base stations if applicable. The handover is triggered by any of the following: based on UE's measurement report, the signal quality of a neighbour cell is better than the current serving cell; based on the measurement of the serving mobile relay base station, the signal quality of the link to the UE is worse than a certain threshold; or based on the measurement of the serving mobile relay base station, the signal quality of a neighbour cell is much better than the current donor base station.

Abstract: In a heterogeneous network based on LTE, the random access, RA, procedure triggered in a macrocell produces transmissions from a UE (20) on the physical random access channel, PRACH, which a picocell eNB (12) can attempt to make measurements of for interference coordination purposes over the X2 interface between the macro eNB (10) and the pico eNB (12). By reconfiguring the UE's behavior during principally the contention-free RA procedure, its transmissions on PRACH are made different to the default such as to be suitable for heterogeneous network interference measurements. This is done by assigning new meanings to certain of the characteristic parameters provided by the macro eNB (10) to the UE (20), such as the RA preamble it uses and the C-RNTI it is assigned during the procedure.

Abstract: A communication system includes a plurality of base stations and a user equipment, wherein the communication link is established between the user equipment and a source base station of the plurality of base stations. A method includes: selecting a target cell and a re-establishment cell of at least one candidate handover base station of the plurality on the basis of a measurement report, the measurement report comprising measurements of attributes of cells of the plurality of base stations for a handover; initiating a handover preparation by transmitting a request from the source base station to the at least one candidate handover base station, wherein the request indicates the target cell and the re-establishment cell; carrying out admission control on the target cell and on the re-establishment cell; initiating the handover by transmitting a handover request acknowledgement from the at least one candidate handover base station to the source base station.

Abstract: A content delivery method employing opportunistic D2D links among UEs, in a two-stage process. In a first stage, content is delivered from a content delivery node (40) to a first tier of target UEs (10, 12, 14, 16) through the core network (30) and conventional cellular communication via a base station or access point (20). In the second stage, the target UEs act as relays for other, 2nd tier UEs (11, 13, 15) which wish to receive the content, by delivering the content over opportunistic D2D links. The process is controlled by a service anchor (50) of an operator providing the content delivery service.

Abstract: A method to provide mobility support of UEs (12) that are served by mobile relay base stations (14), by providing handover of a UE(12) for data traffic only between two mobile relay base stations. This is achieved by information exchanging between the source and target mobile relay stations of the concerned UE in handover, and/or the corresponding donor base stations (13, 11) if applicable. The handover is triggered by any of the following: based on UE's measurement report, the signal quality of a neighbor cell is better than the current serving cell; based on the measurement of the serving mobile relay base station, the signal quality of the link to the UE is worse than a certain threshold; or based on the measurement of the serving mobile relay base station, the signal quality of a neighbor cell (potential donor base station) is much better than the current donor base station.

Abstract: A method and apparatus for analyzing cause of link failure, includes: receiving, by a base station where the user equipment is present when a link failure is observed by the user equipment, identification information transmitted by other base stations or the user equipment, the identification information including: identification associated with the user equipment and/or identification of the user equipment in the base station; and determining, by the base station when it determines that the identification information is stored in the base station, that the link failure is resulted from a handover preparation failure.

Abstract: A wireless communication system includes a virtual terminal formed from one or more independent devices, a terminal management entity for managing the virtual terminal. The devices may be independent physical devices (smartphones, tablet computers), virtual machines/modules of physical devices, or a combination of both. The virtual terminal and terminal management entity communicate via a base station and/or access point. The terminal management entity creates a service ID for a service to be provided to the virtual terminal, the service ID being shared by the one or more independent devices, each having its own device ID. The TME forms an association of the virtual terminal with the network through use of a multi-homing transport protocol such as SCTP, the association supporting the service by using the service ID. For service delivery, paging and handover purposes the devices of the virtual terminal are treated as a single entity by the TME.

Abstract: A method and apparatus for judging type of a handover failure. The method includes: judging type of a handover failure, by a base station of a serving cell where UE is present before a connection failure occurs, according to related information and a maximum measurement result of a downlink signal measured by the UE at the serving cell. The type of a handover failure in a heterogeneous network may be accurately judged by taking the maximum measurement result of the downlink signal of the serving cell into account, thereby enabling the network side to adjust a handover parameter based on the judgment result of the type of the handover failure, so as to ensure the performance of the network.

Abstract: A communications system comprises a gateway device, a data server and neighbouring devices neighbouring the gateway device, wherein the gateway device is arranged to receive monitoring information from one or more sensors and to forward the monitoring information to the data server; the data server is arranged to receive the monitoring information; the communications system is arranged to generate an alert and initiate relaying if the connection between the gateway device and the data server is at risk; the gateway device is arranged to identify a relaying group of one or more neighbouring devices that can relay the monitoring information from the gateway device to the data server; and to send the monitoring information to the one or more neighbouring devices in the relaying group; each member of the relaying group is arranged to receive the monitoring information sent to it, and to relay the monitoring information to the data server; and the data server is arranged to receive the monitoring information.

Abstract: A method to provide mobility support of UEs (12) that are served by mobile relay base stations (14), by providing handover of a UE(12) for data traffic only between two mobile relay base stations. This is achieved by information exchanging between the source and target mobile relay stations of the concerned UE in handover, and/or the corresponding donor base stations (13, 11) if applicable. The handover is triggered by any of the following: based on UE's measurement report, the signal quality of a neighbour cell is better than the current serving cell; based on the measurement of the serving mobile relay base station, the signal quality of the link to the UE is worse than a certain threshold; or based on the measurement of the serving mobile relay base station, the signal quality of a neighbour cell (potential donor base station) is much better than the current donor base station.

Abstract: Embodiments of the present disclosure provide an information interaction method, a base station and a communication system. The information interaction method includes: a first base station notifies a second base station that a second cell is deployed and a first cell is to be shrunk in coverage; and the first base station receives a handover request transmitted by the second cell for handing a UE over to the first cell, the handover request includes reestablishment cell information containing at least information on the second cell. With the embodiments of the present disclosure, not only a reestablishment failure will not be resulted after a handover failure, but also signaling overhead may be saved.

Abstract: A method and apparatus for information processing and a communication system. The method includes: storing, when user equipment detects that a failure occurs, information related to the failure, and reserving the stored information related to the failure. In this way, when the network side obtains the information related to failure at each time occurrence of failure, the handover parameter may be configured according to the information, thereby reducing occurrence of failure.

Abstract: A method to provide mobility support of UEs (12) that are served by mobile relay base stations (14), by providing handover of a UE (12) for data traffic only between two mobile relay base stations. This is achieved by information exchanging between the source and target mobile relay stations of the concerned UE in handover, and/or the corresponding donor base stations (13, 11) if applicable. The handover is triggered by any of the following: based on UE's measurement report, the signal quality of a neighbour cell is better than the current serving cell; based on the measurement of the serving mobile relay base station, the signal quality of the link to the UE is worse than a certain threshold; or based on the measurement of the serving mobile relay base station, the signal quality of a neighbour cell (potential donor base station) is much better than the current donor base station.

Abstract: The invention provides for association of data streams (and/or logical channels) with individual carriers (cells), and independent buffer status reporting per carrier for terminals with more than one uplink carrier configured. In a “Small Cell” scenario for 3GPP LTE, a terminal may be simultaneously served by a macro cell and one or more small cells. These may operate at different frequencies, have different traffic loading and support different QoS (Quality of Service). The invention allows independent control of traffic on the uplinks to the macro cell and the small cells, which can be used to optimize the user experience in relation to the available resources at any given time/location, and allows particular data to be routed via particular cells.

Abstract: A cloud-based wireless communication system (1) comprising user devices (12) arranged to receive services through any of a plurality of cloud-based virtual networks. The system has a plurality of base stations or access points (14), a user device (12) being arranged to wirelessly connect to any of the virtual networks via at least one base station (14) in order to receive from a virtual network a specific service for which a user of the user device has subscribed. There are virtual service anchors or vSAs (26) in the cloud, each virtual service anchor provided for a respective service provided by its virtual network. Thus, one vSA (26) handles resource allocation for all users of one service in one virtual network. Each vSA (26) receives content access requests (S10) from user devices (12) indicating content to be accessed in that vSA's service, the content stored by at least one content delivery node in the cloud.

Abstract: Embodiments of the present disclosure provide an information acquiring method, parameter optimizing method and apparatuses thereof and a system. The method includes: receiving, by a first base station, information transmitted by user equipment, or a second base station, or a third base station; wherein, the information comprises relevant information used by a network side to determine cell types of the first base station and the second base station when handover initiation or link failure occurs, or comprises an absolute time when handover initiation or link failure occurs in the user equipment. With this method, cell types corresponding to coverage ranges of cells may be configured according to dynamically adjusted parameter ranges, thereby further configuring triggering conditions corresponding to the cell types, and satisfying traffic demands when the cell ranges change dynamically.