Abstract: A method and system is provided for re-routing a flow of packets in a packet-switched network at a rerouting time. In one embodiment, the method comprises accepting packets in a switch, routing the flow of the packets to a first destination via the switch according to a switch flow rule, receiving an updated switch flow rule from a controller before the rerouting time, the updated switch flow rule defining the rerouted flow of packets, and rerouting the flow of packets according to the updated switch flow rule at a rerouting time indicated by a packet of the accepted packets.

Abstract: The present invention discloses a method and system for processing frequency offset, the method includes: obtaining a current frequency offset state; determining whether the current frequency offset state is consistent with a historical effective frequency offset state; wherein the historical effective frequency offset state is a frequency offset state corresponding to a correct decoding result; if it is determined yes, performing a pre-compensation to a fine frequency offset estimation according to the historical effective frequency offset state. The present application solves the problem that inaccurate frequency offset estimation makes it unable to perform frequency offset compensate.

Abstract: Embodiments of the disclosure relate to suppressing an uplink radio frequency (RF) interference signal(s) in a remote unit in a wireless distribution system (WDS) using a correction signal(s) relative to the uplink RF interference signal(s). A remote unit in a WDS is configured to receive an uplink RF signal including an uplink RF communications signal(s) and an uplink RF interference signal(s). To mitigate adverse impacts of the uplink RF interference signal(s) on the uplink RF communications signal(s), the remote unit generates an RF correction signal(s) based on identified interference characteristics of the uplink RF interference signal. The remote unit combines the RF correction signal(s) with the uplink RF signal to suppress the uplink RF interference signal(s) to a predetermined level. By doing so, it is possible to mitigate the adverse impacts of the uplink RF interference signal(s), thus preserving integrity and quality of the uplink RF communications signal(s).

Abstract: A communications system communicating data to/from a user device including: infrastructure equipment forming a mobile communications network configured to transmit/receive data to/from the user device via a wireless access interface. The user device can receive an indication from the infrastructure equipment of a location and duration of a temporal response window for receiving response messages, received in response to access requests messages, transmit to the infrastructure equipment an access request message for requesting access to the wireless access interface, and receive a response message from the infrastructure equipment in response to the access request message. The infrastructure equipment can process an access request message and generate the response message, transmit the response message to the user device, and transmit the response message within the temporal response window, and the user device is configured to receive the response message within the temporal response window.

Abstract: A base station (13) is configured to receive, from a Machine-to-machine (M2M) terminal (11) or a core network (14), history information indicating whether or not specific coverage enhancement processing was executed in previous communication with the M2M terminal (11). Further, the base station (13) is configured to control communication using the specific coverage enhancement processing between the M2M terminal (11) and the base station (13) based on the history information received from the M2M terminal (11) or the core network (14). It is thus possible to contribute to improving efficiency of determination regarding whether to apply a special coverage enhancement processing to the M2M terminal.

Abstract: A Radio Access Network (RAN) node (e.g., BSS) and method are described herein that introduce one or more bits in any of the current system information (SI) messages or in a new SI message to ensure that a wireless device upon receipt of the SI message knows if a cell supports a Mobile Station Assisted Dedicated Core Network Selection such that the wireless device can transmit uplink Radio Link Control (RLC)/Media Access Control (MAC) radio blocks that will match the capability of the RAN node (e.g., BSS). In addition, the present disclosure relates to the wireless device and method for receiving a SI message from the RAN node (e.g., BSS) that indicates if a cell supports the Mobile Station Assisted Dedicated Core Network Selection such that the wireless device can transmit uplink RLC/MAC radio blocks that will match the capability of the RAN node (e.g., BSS).

Abstract: An apparatus and method in a wireless communication system. The apparatus includes a dynamic network planning trigger unit and a master user equipment selecting unit. The dynamic network planning trigger unit triggers, based on a predetermined trigger event, a dynamic network planning in an area managed by the apparatus. The dynamic network planning includes selection of a master user equipment used for device-to-device communication, and the master user equipment receives signals from a base station during the device-to-device communication process and relays signals between the base station and a slave user equipment. The master user equipment selecting unit selects, from user equipment in the area according to quality of channels between the user equipment and the base station, one or more user equipment as master user equipment, distances between the master user equipment being greater than the intervals.

Abstract: A method for a terminal performing redistribution target selection in a wireless communication system, and an apparatus supporting the same are provided. The terminal receives redistribution parameters from a network, and performs redistribution target selection based on UE_ID, wherein the UE_ID can be a function of a time varying index and a UE identity.

Abstract: A transmitting apparatus is disclosed. The transmitting apparatus includes an encoder to perform channel encoding with respect to bits and generate a codeword, an interleaver to interleave the codeword, and a modulator to map the interleaved codeword onto a non-uniform constellation according to a modulation scheme, and the constellation may include constellation points defined based on various tables according to the modulation scheme.

Abstract: A transmitting apparatus is disclosed. The transmitting apparatus includes an encoder to perform channel encoding with respect to bits and generate a codeword, an interleaver to interleave the codeword, and a modulator to map the interleaved codeword onto a non-uniform constellation according to a modulation scheme, and the constellation may include constellation points defined based on various tables according to the modulation scheme.

Abstract: Disclosed aspects relate to window management in a stream computing environment. An indication of congestion may be detected with respect to the stream computing environment. Based on the indication of congestion, a set of window configurations in the stream computing environment may be determined. In response to determining the set of window configurations in the stream computing environment, the set of window configurations may be established in the stream computing environment.

Abstract: A first terminal device communicates with a second terminal device through a fourth terminal device. An acquisition unit acquires a maximum transmission delay time by referring to a transmission delay time with respect to each of the second terminal device through the fourth terminal device. A communication unit transmits data to each of the second terminal device through the fourth terminal device. The communication unit prohibits, when transmission of the data is ended, new data from being transmitted over a prohibition period based on the maximum transmission delay time acquired in the acquisition unit.

Abstract: In this device: a gain calculator (101) uses a function in which the variable is a first resource amount from among the resource amounts possessed by an operator in question, and calculates a second resource amount at which the maximum gain is reached in the function of the operator to which the device in question belongs, the first resource amount being a resource amount allocated to a terminal belonging to another operator; a transmitter/receiver (102) transmits the second resource amount to the manager (300), and receives, from the manager (300), the minimum value among second resource amounts calculated in each of the operators; and the allocation unit (103) allocates resources to the signal of the terminal belonging to the operator in question and to the terminal belonging to the other operator on the basis of the minimum value among the second resource amounts calculated by each of the operators.

Abstract: In a cellular communication system, a UE device being served by a serving communication station is instructed to transmit an uplink signal in accordance with an uplink signal configuration. The uplink signal configuration information is sent to a non-serving communication station in an inactive state where the non-serving communication station cannot provide wireless service. The uplink signal configuration information allows the non-serving communication station to configure its receiver to receive the uplink signal from the UE. Based, at least in part, on information pertaining to the uplink signal received by the non-serving communication station and then sent to the serving communication station, the serving communication station determines whether the UE device is sufficiently near to the non-serving communication station to receive wireless service from the non-serving communication station, in which case the non-serving communication station is activated.

Abstract: Provided are a method and apparatus for determining connection configuration between a user equipment (UE) and a base station (ENB) and performing handover in a wireless communication system supporting dual connectivity. The method of setting a connection configuration for a UE in a wireless communication system supporting dual connectivity may include: detecting occurrence of a handover event; selecting a macro ENB with the highest signal strength among neighboring macro ENBs and a small ENB with the highest signal strength among neighboring small ENBs; checking whether dynamic association is allowed in dual connectivity; and determining the connection configuration for the UE on the basis of the selected ENBs and checking result.

Abstract: Embodiments of the present invention address deficiencies of the art in respect to connectivity management in a heterogeneous network and provide a method, system and computer program product for resilient and reliable end-to-end connectivity in a heterogeneous network. In one embodiment of the invention, a method for resilient and reliable end-to-end connectivity in a heterogeneous network environment can be provided. The method can include creating an instance of an abstracted network resource model (NRM) for a heterogeneous network environment of different network resource nodes. The method further can include binding an application endpoint in the instance of the abstracted NRM with a connectivity endpoint for a first of the different network resource nodes. The method yet further can include detecting an outage in the first of the different network resource nodes.

Abstract: A method of encapsulating data and a single frequency network configured to perform the method are disclosed. A content stream of data packets is received, and the data packets in the content stream are formatted in accordance with a first protocol. Information identifying a container size established for the content stream is received. The data packets formatted in accordance with the first protocol are fragmented and packed to form data units formatted in accordance with a second protocol, and the data units are sized based on the container size. The data units formatted in accordance with the second protocol are encapsulated to form second protocol data packets. The second protocol data packets are provided to a transmitter that is synchronized to one or more transmitters in a single frequency network so that each transmitter in the single frequency network broadcasts a same signal that includes the second protocol data packets.

Abstract: Methods and apparatus for multi-carrier communication with variable channel bandwidth are disclosed, where the time frame structure and the OFDM symbol structure are invariant and the frequency-domain signal structure is flexible. In one embodiment, a mobile station, upon entering a geographic area, uses a core-band to initiate communication and obtain essential information and subsequently switches to full operating bandwidth of the area for the remainder of the communication. If the mobile station operates in a wide range of bandwidths, the mobile station divides the full range into sub-ranges and adjusts its sampling frequency and its FFT size in each sub-range.

Abstract: Examples relate to packet tagging in Software Defined Networks (SDN). In an example, at least one SDN switch of an SDN marks a packet passing through the SDN switch with a packet tag, wherein the packet tag comprises an identifier of the SDN switch and a digest of a set of network forwarding rules of the SDN switch. Some examples generate, by a verifier, a verifier tag comprising the identifier of the at least one SDN switch and the digest of the set of network forwarding rules of the at least one SDN switch obtained from a network rules table and a network topology table stored in the verifier. Some examples receive, at a particular network element and from a verifier of the SDN, a request for attestation of the packet. Some examples check, by a verification engine, the packet tag against the verifier tag.

Abstract: A method for transmitting broadcast signals from a group of base stations to terminals of a wireless communication system. Each base station having a coverage area. The coverage areas of the base stations of the group are distributed geographically such as to serve a geographical area. Since the broadcast signals are of limited duration and are transmitted in a frequency band used by all of the base stations of the group, the base stations of the group are time-synchronized in relation to one another. The broadcast signals from the base stations of the group are time-multiplexed. In addition, the wireless communication system has multiple geographical regions. Each region includes multiple groups of base stations), and the broadcast signals of different geographical regions are time-multiplexed.