Abstract: A method for a coordinated transmission in a wireless communication system. The method includes processing feedback information from multiple transmit points (TPs) operating in license assisted access (LAA) cells, generating scheduling information for the coordinated transmission by the multiple TPs to a user equipment (UE) in accordance with the feedback information, transmitting the scheduling information to the multiple TPs, and receiving the feedback information from the multiple TPs.

Abstract: A user equipment (UE) in a wireless network having two-dimensional antenna systems performs a method of codebook sampling. The method includes receiving from an eNodeB (eNB) an indication of a restricted subset M of vertical precoding matrices, wherein M is less than a total number of vertical precoding matrices N in a codebook, the codebook comprising a plurality of vertical precoding matrices and horizontal precoding matrices. The method also includes feeding back vertical precoding matrix indicators (V-PMI) to the eNB based on the restricted subset of vertical precoding matrices.

Abstract: A method and an apparatus for control information resource allocation for device to device (D2D) communications. The method includes receiving a network allocation of resource configuration to the UE. The method further includes selecting a set of resources from the network allocation of resource configuration based on a priority rule. The method also includes transmitting the selected set of resources to one or more other UEs.

Abstract: A method for measuring a downlink signal in a wireless communication system is provided. The method includes receiving a downlink signal from an eNodeB (eNB) using one or more carriers. The downlink signal includes one or more subframes during on an ON duration and an OFF duration in the one or more carriers. The method further includes measuring the one or more subframes included in the downlink signal to generate channel state information in accordance with a set of configuration parameters and transmitting an uplink signal including the channel state information to the eNB.

Abstract: A method of a base station (BS) to implement a listen-before-talk (LBT) protocol is provided. The method includes generating for transmission at least one of a discovery reference signal (DRS) or a data signal. The method also includes initiating an LBT protocol based on a single sensing interval to access a channel and transmit the DRS in contiguous orthogonal frequency-division multiplexing (OFDM) symbols. The method further includes initiating an LBT protocol with random back-off to access the channel and transmit the data signal, where a back-off counter value of the LBT protocol with random back-off does not decrement when the DRS is transmitting in the channel.

Abstract: Methods and apparatuses for cell detection, synchronization and measurement on unlicensed spectrum. A method for receiving a discovery reference signal (DRS) includes identifying, based on a DRS measurement timing configuration (DMTC), a DRS detection/measurement gap duration and a periodicity; and listening for the DRS on a carrier in an unlicensed spectrum during the identified gap duration at the identified periodicity. An apparatus for an eNodeB associated with a cell includes a controller and a transceiver. The controller is configured to configure a DMTC including a DRS detection/measurement gap duration and periodicity. The transceiver is configured to transmit the DRS on a carrier in an unlicensed spectrum during the gap duration at the periodicity.

Abstract: A user equipment, apparatus, and method are provided for wireless communication in a hybrid communication network. A method includes transmitting, by a first user equipment (UE), a scheduling request to a first eNodeB (eNB). The scheduling request indicates that the UE is capable of device-to-device (D2D) communications. The method includes receiving, by the first UE, a first scheduling assignment (SA) from the first eNB. The first SA indicates resources to be used by the first UE for device-to-device (D2D) communications with the first eNB. The method includes communicating, by the first UE, with the first eNB according to the first SA.

Abstract: A method includes detecting a device to device (D2D) synchronization signal of a neighbor base station, transmitted from at least one other UE associated with the neighbor base station through a transceiver, determining at least one UE receive (RX) resource pool configured by the neighbor base station based on the D2D synchronization signal of the neighbor base station, and monitoring a D2D discovery or communication signal transmitted from the at least one other UE according to the at least one UE RX resource pool through the transceiver. A method includes determining at least one UE RX resource pool for at least one device associated with a base station, each UE RX resource pool comprising a repetition of a Scheduling Assignment (SA) pool and a data pool with a scheduling cycle, the SA pool comprising a SA bitmap, and the data pool comprising at least one repeated data bitmap.

Abstract: A user equipment (UE) is configured to perform a Hybrid Automatic Repeat Request (HARQ) in an un-licensed system. The UE includes at least one antenna configured to communicate with a base station. The UE also includes processing circuitry. The processing circuitry is configured to: send and receive data through the at least one antenna, in response to failing to decode a transport block transmitted by a first downlink carrier, transmit a negative acknowledgement message to the base station, and receive a re-transmission of the transport block from a second downlink carrier. The first downlink carrier comprises a unlicensed spectrum carrier and the second downlink carrier is different from the first downlink carrier.

Abstract: An eNodeB operated by a first operator is able to align an ON-OFF cycle operation for interference avoidance. The eNodeB receives, from another eNodeB operated by a second operator a physical broadcast channel (PBCH) and a physical downlink shared channel (PDSCH). A transmission coverage of the eNodeB partially overlaps with a transmission coverage of the other eNodeB. The PBCH carries a master information block (MIB), and the PDSCH carries a single system information block (SIB) identifying available unlicensed channel and including public land mobile network (PLMN) identities for networks operating using the unlicensed channel. The eNodeB uses the MIB and SIB1 to identify that the second eNodeB is operated by the second operator.

Abstract: A method of assigning a device ID of a device-to-device network to a mobile station includes: selecting a subset from a set of parameters from which the device ID is determined, each parameter in the set having a number of bits for complete representation, the subset comprising a number Nd2d of parameters used to determine the device ID; determining a number L of device ID bits to represent the device ID; dividing the L device ID bits into a group of l1 indicator bits and a group of l2 identifier bits, wherein l2 is the difference between the number L of device ID bits and the number l1 of bits allocated to the group of indicator bits; assigning bit values to the l1 indicator bits; allocating a number Ljp of the l2 identifier bits to each of the parameters in the subset; and assigning bit values the l2 identifier bits.

Abstract: A Device to Device (D2D) user equipment (UE) is configured to support synchronization in a D2D network. The D2D UE includes an antenna configured to communicate via a D2D communication. The D2D UE also includes processing circuitry configured to enter a communication Mode 2 when certain conditions are met. The certain conditions include: when a first timer (T310) for detecting radio link failure is running, a second timer (T311) for initiating the connection reestablishment is running, or a third timer (T301) for requesting connection reestablishment is running. In communication Mode 2, the D2D UE, on its own, selects resources from resource pool(s) to transmit D2D data and D2D control information. The processing circuitry further configured to exit the communication Mode 2 and enter a communication Mode 1 when the certain condition is no longer met. In communication Mode 1, the D2D UE uses resources configured by another station.

Abstract: A Device to Device (D2D) user equipment (UE) is configured to support synchronization (sync) in a D2D network. The D2D UE includes an antenna configured to communicate via a D2D communication. The D2D UE also includes processing circuitry configured to communicate with a second portable terminal via the D2D communication. The processing circuitry is further configured to: derive a transmission (TX) timing from a synchronization (sync) source; and transmit a D2D Sync Signal (D2DSS) and Physical D2D Sync Channel (PD2DSCH) configured to indicate a hop number from the sync source. The hop number is indicated via the preamble sequence set and the indicator in PD2DSCH.

Abstract: Adaptation of measurement procedures for cell detection and association provide more accurate and frequent reports for use by the network, to enhance cell association. A user equipment receives, within a configured measurement bandwidth, orthogonal frequency division multiplexing symbols comprising discovery reference signals (DRS). For subframes in which the DRS are transmitted, a discovery reference signal received quality (D-RSRQ) is determined from the DRS within the received symbols as a ratio of discovery reference signal received power (D-RSRP) to carrier discovery received signal strength indicator (D-RSSI), where the D-RSRP is measured in symbols containing DRS resource elements and the D-RSSI is measured in all symbols in subframes containing the DRS. For a UE configured to also measure common reference signals, non-DRS measurements are suspended upon deactivation of a secondary cell, and measurement timing of the DRS during a deactivation period is based on a measurement timing parameter.

Abstract: Drive testing for network optimization has been supplemented by the use of information measuring radio conditions collected by mobile terminals (i.e. UEs). To improve the user experience of multicast and broadcast services based on cellular telecommunications networks, such as MBMS and eMBMS, a mechanism is described that adapts UE-based reporting of measurement reports to multicast and broadcast services.

Abstract: Coordinate multi-point (CoMP) transmission is facilitated by resolving collisions between feedback reporting. Based upon the conditions within the network, collision resolution may be by dropping a channel report during a subframe, multiplexing channel reports from a plurality of user equipment, compressing channel reports from a plurality of user equipment, and combined reporting, either through joint reports or by using carrier aggregation, for conditions between a user equipment and a plurality of transmission points. New signaling and reporting formats facilitate selection of a collision resolution suitable for current network conditions.

Abstract: Coordinate multi-point (CoMP) transmission is facilitated by resolving collisions between feedback reporting. Based upon the conditions within the network, collision resolution may be by dropping a channel report during a subframe, multiplexing channel reports from a plurality of user equipment, compressing channel reports from a plurality of user equipment, and combined reporting, either through joint reports or by using carrier aggregation, for conditions between a user equipment and a plurality of transmission points. New signaling and reporting formats facilitate selection of a collision resolution suitable for current network conditions.

Abstract: User equipment for wireless communication with at least one base station includes a transceiver operable to communicate with the at least one base station by transmitting radio frequency signals to the at least one base station and by receiving radio frequency signals from the at least one base station. The transceiver is configured to receive a discovery signal from a base station of the at least one base station, the discovery signal comprising a discovery signal identifier. The transceiver is also configured to receive a synchronization signal or reference signal, the synchronization signal or the reference signal comprising a physical cell identifier. The user equipment also includes processing circuitry configured to determine whether the discovery cell identifier matches the physical cell identifier.

Abstract: A method includes scheduling at least one resource for a Device-to-Device (D2D) transmission control channel (DCCH) carrying a D2D control information (D2DCI) message, transmitting, by a first UE, the DCCH on the at least one DCCH resource to at least one second UE, scheduling at least one resource for a D2D data channel (DDCH), and transmitting, by the first UE, the DDCH on the at least one DDCH resource to the at least one second UE. A UE includes one or multiple antenna, and a processing circuitry configured to schedule at least one resource for a DCCH, transmit the DCCH on the at least one DCCH resource, to at least one second UE through the one or more multiple antenna, schedule at least one resource for a DDCH, and transmit the DDCH on the at least one DDCH resource, to the at least one second UE.

Abstract: A method and apparatus for managing data in a software defined network. The apparatus is configured to receive control information related to a source node and a target node from a plurality of network devices in the software defined network. The apparatus is also configured to identify a route for data forwarding between the source node and the target node based on the control information. The apparatus is also configured to request data forwarding to the plurality of network devices according to the route. The source node or the target node can be at least one of a user equipment (UE), and a cellsite node including at least a base station.