Abstract: A terminal apparatus detects a downlink frame timing based on a synchronization signal in EUTRAN, receives a TA (Timing Advance) command from a base station apparatus of the EUTRAN, transmits an uplink signal in the EUTRAN to the base station apparatus of the EUTRAN at a timing based on at least the downlink frame timing and a value of the TA command, and transmits a signal between terminal apparatuses to another terminal apparatus at the same timing.

Abstract: Communication resources are appropriately used. An information processing device is an information processing device including an acquisition unit and a control unit. Here, the acquisition unit acquires a relative priority of each information processing device in a network built through autonomous wireless communication of a plurality of information processing devices. In addition, the control unit performs control such that a communication resource of the network is allocated based on the priority (a relative priority of each information processing device in the network) acquired by the acquisition unit.

Abstract: Techniques are described for wireless communication. A method for wireless communication may include identifying interference at a first node operating in a shared radio frequency spectrum band. The interference may be caused by a second node operating in the shared radio frequency spectrum band. The second node may operate asynchronously to the first node in the shared radio frequency spectrum band. The method may also include adaptively enabling, based at least in part on the identified interference, a synchronization of the first node with at least a third node in the shared radio frequency spectrum band.

Abstract: A MAC protocol, useful for WLANs, is provided for random access over a channel. The protocol includes three concurrent processes. The channel includes a contention subchannel and a transmission subchannel. In the contention process, all nodes use the standard RTS/CTS mechanism operated on the contention subchannel to contend for a transmission right. When one node gains the right, all the nodes store the contention result into their respective contention queue (CQ) buffers. In the transmission process, the nodes sequentially transmit their data over the transmission subchannel according to the order of the nodes stored in the CQ buffers. When one node finishes transmission, the CQ buffers are updated. The contention and transmission processes are connected by the queuing process for dynamically updating each node's CQ buffer. When OFDM is used in a random-access system, numbers of data subcarriers in both subchannels for maximizing the system throughput are given.

Abstract: A broadcasting transmitter for transmitting a broadcast signal according to an embodiment of the present invention comprises: an Internet protocol (IP) packet generator for generating first IP packets including broadcast data for a broadcast service and generating a second IP packet including service acquisition information that includes information required for quickly acquiring the broadcast service; a link layer packet generator for generating first link layer packets including the first IP packets; and a broadcast signal generator for generating a broadcast signal that includes the first link layer packets and the second IP packet.

Abstract: In some embodiments, a user equipment device (UE) may be configured to perform handover of a communication session from a first packet data network (PDN) to a second PDN. The UE may include a radio and processing circuitry coupled to the radio and configured to interoperate with the radio. The radio may include one or more antennas for performing wireless communications over at least a first packet data network (PDN) (i.e., packet-switched network) and a second PDN. The UE may be configured to communicate over the first PDN according to first context information that was assigned to the UE and initiate a handover operation from the first PDN to the second PDN. In response to initiating the handover operation, the UE may communicate over the second PDN using the first context information for at least a first time duration.

Abstract: Devices and techniques for reorder resilient transport are described herein. A device may store data packets in sequential positions of a flow queue in an order in which the data packets were received. The device may retrieve a first data packet from a first sequential position and a second data packet from a second sequential position that is next in sequence to the first sequential position in the flow queue. The device may store the first data packet and the second data packet in a buffer and refrain from providing the first data packet and the second data packet to upper layer circuitry if the packet order information for the first data packet and the second data packet indicate that the first data packet and the second data packet were received out of order. Other embodiments are also described.

Abstract: In a handover procedure between cells under different radio base stations (eNB), “RRC diversity” is implemented. A mobile communication method includes: a step A of transmitting, by a radio base station (eNB #1), “CoMP preparation” to a radio base station (eNB #10); a step B of transmitting, by the radio base station (eNB #10), setting information on a cell (#10) to the radio base station (eNB #1); a step C of conducting, by the radio base station (eNB #1), setting of the mobile station (UE) to perform CoMP transmission-reception; a step D of giving, by the mobile station (UE), the radio base station (eNB #1) notification that radio quality in the cell (#10) satisfies a predetermined condition; and a step E of instructing, by the radio base station (eNB #1), the radio base station (eNB #10) to start scheduling for the mobile station (UE).

Abstract: A method, an apparatus, and a computer program product for wireless communication are provided. The apparatus determines a subset of subchannels for a first cell, the subset of subchannels configured to reduce interference to at least a second UE in a second cell, determines whether a first UE in the first cell is interfering with a second UE in a second cell, and allocates at least one subchannel to the first UE from the subset of subchannels when the first UE in the first cell is interfering with the second UE in the second cell.

Abstract: A MAC protocol, useful for wireless local area networks (WLANs), is provided for improving throughput efficiency. The protocol includes three concurrent processes, and the channel is divided into a contention subchannel and a transmission subchannel. In the contention process, all nodes use the standard RTS/CTS mechanism operated on the contention channel to contend for a right of transmission. When one node gains the right, all the nodes store the contention result into their respective contention queue (CQ) buffers. In the transmission process, the nodes sequentially transmit their data over the transmission channel according to the order of the nodes stored in the CQ buffers. When one node finishes data transmission, the CQ buffers are updated. The contention process and the transmission process are connected by the queuing process, where each node dynamically updates its own CQ buffer according to the contention result and each instance of data transmission.

Abstract: The present disclosure relates to systems, methods, and devices for performing measurements on a carrier associated with a deactivated cell in a cellular communications system. In some embodiments, a method of operation for a wireless device for determining whether to perform one or more measurements on a carrier associated with a deactivated cell comprises acquiring at least one parameter related to a periodicity (Dp) of a discovery signal transmitted on one or more cells of a carrier with the deactivated cell, acquiring a measurement cycle parameter (Sc) for performing one or more measurements on one or more cells on the carrier, comparing the periodicity (Dp) of the discovery signal and the measurement cycle parameter (Sc), and deciding whether to perform the one or more measurements for the cells on the carrier based on the comparison of the periodicity (Dp) of the discovery signal and the measurement cycle parameter (Sc).

Abstract: A measuring system serves for measuring a broadband measurement signal. It contains a receiving unit for receiving the measurement signal and a processing unit for processing the measurement signal. The receiving unit is configured to receive the measurement signal with a broad bandwidth within a first measurement run. The processing unit is configured to recover information from the measurement signal received with a broad bandwidth. In turn, with the assistance of the information, the receiving unit is configured to receive at least one first frequency subdivision of the measurement signal with a narrow bandwidth within a second measurement run.

Abstract: A beamforming configuration is changed during a cyclic prefix that precedes a symbol period. For example, the beamforming configuration for a transmitter can be changed during an orthogonal frequency-division multiplexing (OFDM) cyclic prefix that precedes a fast Fourier transform (FFT) window. At the receiver, the cyclic prefix is reconstructed based on the chips received during FFT window. In this way, there is no loss of data signaling due to the transmitter reconfiguring its beamforming.

Abstract: A method and a resource broker are provided to control a conference session. The resource broker receives, from a conference controller, a message requesting to set up a conference communication for a participant. The message indicates whether a terminal of the participant supports selective forwarding. The resource broker verifies the availability of local selective forwarding and multipoint control resources. Based on the capabilities of the terminal and based on local resource availability, a reply is sent to the conference controller, indicating that the conference communication should be set up in selective forwarding or multipoint control mode, using local resources or resources of a network cloud. When a new participant is added or when a monitoring agent reports a change of availability of the local resources, the conference communication may be moved between the network cloud and the local resources, or change between selective forwarding and multipoint control modes.

Abstract: A method for optimizing throughput of a network with stations adapted to transmit data to an access point includes the step of determining a respective required throughput for each station based on: respective time periods required for decreasing a count of a respective back-off counter associated with each of the stations, a transmission packet length of the respective station, and a probability of successful transmission for of the respective station. The respective required throughput so determined is a function of a respective transmission attempt rate for the station. The method further includes the step of determining the respective transmission attempt rate for each station for maximizing a sum of the respective required throughput such that a respective fixed throughput is provided for inelastic data flow in the network, a respective proportional throughput ratio is provided for elastic data flow in the network, and the throughput of the network is maximized.

Abstract: Aspects of the present disclosure provide a self-contained subframe structure for time division duplex (TDD) carriers. Information transmitted on a TDD carrier may be grouped into subframes, and each subframe can provide communications in both directions (e.g., uplink and downlink) to enable such communications without needing further information in another subframe. In one aspect of the disclosure, a single subframe may include scheduling information, data transmission corresponding to the scheduling information, and acknowledgment packets corresponding to the data transmission. Furthermore, the subframe may additionally include a header and/or a trailer to provide certain bi-directional communications functions.

Abstract: The present invention relates to a method and an apparatus for switching a data path in a wireless communication system supporting device-to-device (D2D) communication. The method for switching a path of a base station in a wireless communication system supporting device-to-device communication, according to the present invention, comprises the steps of: receiving, from a first terminal, a measurement report including a D2D identifier of a second terminal that performs a direct communication with the first terminal; sending a query to a D2D server for a network identifier corresponding to the D2D identifier of the second terminal; and determining whether to switch a direct path between the first terminal and the second terminal to a local path on the basis of the network identifier of the second terminal obtained from the D2D server.

Abstract: The present disclosure provides a method for feeding back aperiodic CSI in a flexible TDD reconfiguration cell. The method includes a UE receiving information about signaling transmitted from an eNB to acquire locations of subframes corresponding to CH and CL, wherein CH and CL correspond to different subframe sets, respectively. The method also includes the UE detects UL DCI information carrying an aperiodic CSI request, on a CSI request subframe. The method also includes the UE feeds back aperiodic CSI specific to a corresponding CSI subframe set to the eNB, on a corresponding UL subframe. The embodiments of the present disclosure, according to another aspect, provide a terminal.

Abstract: The present invention provides a method of transmitting broadcast signals. The method includes, generating input packets including broadcast content data; generating a link layer packet by using the generated input packets, wherein the link layer packet includes a link layer header and a link layer payload including the generated input packets, wherein the link layer header includes a count field indicating number of the input packets included in the link layer payload, wherein the link layer header further includes a length part, wherein the length part includes a plurality of length fields as many as that the count field indicates, wherein each of the length fields indicates length of the each input packets included in the link layer payload; generating a broadcast signal including the generated link layer packet; and transmitting the broadcast signal.

Abstract: Various techniques for partitioning an overlay network is disclosed herein. In certain embodiments, an overlay network can be partitioned into overlay partitions with manageable sizes. Each overlay partition can independently manage and update reachability information only for end points that belong to a virtual network with at least one end point in the overlay partition. Thus, each overlay partition can operate independently from others to achieve fast reachability updating for relocated virtual machines or other end points.