Abstract: A medical network service can replace or supplement some or all of an expensive internally staffed clinical facility network with a cloud-based networking service. The medical network service in certain embodiments can provide networking services via software as a service technologies, platform as a service technologies, and/or infrastructure as a service technologies. The medical network service can provide these services to large existing clinical facilities such as metropolitan hospitals as well as to smaller clinical facilities such as specialized surgical centers. The medical network service can replace and/or supplement existing IT networks in hospitals and other clinical facilities and can therefore reduce costs and increase security and reliability of those networks. In addition, the medical network service can provide synergistic benefits that can improve patient outcomes and patient care.

Abstract: Disclosed are a data transmission method and device for device to device (D2D) communication, the method comprising: determining D2D communication destinations corresponding to a user equipment (UE) of a transmitting end; allocating a corresponding resource for each D2D communication destination; according to the resource corresponding to each D2D communication destination, generating a medium access control protocol data unit (MAC PDU) corresponding to the D2D communication destinations, and transmitting the MAC PDUs using the resource corresponding to the D2D communication destinations. The present invention separately generates a MAC PDU for each D2D communication destination of a UE of a transmitting end, thus preventing the data from one device to different D2D communication destination devices from being multiplexed into one MAC PDU, further reducing header overhead of the MAC PDU and eliminating unnecessary blind detection of a device of a receiving end, thereby saving power.

Abstract: A network system includes a communication apparatus, and a control apparatus configured to control the communication apparatus. The communication apparatus includes a memory configured to store program instructions, and a processor configured to execute the instructions to receive an address of a destination virtual machine from the control apparatus, receive a packet from a source virtual machine, identify, based on the address of the destination virtual machine corresponding to the received packet, an identifier of an edge node connected to the destination virtual machine, and add the identifier of the edge node to the received packet.

Abstract: Methods, systems, and devices for wireless communications are described. Some wireless communications systems may support communications between a base station and a user equipment (UE) on multiple carriers. A UE may maintain a connection with a base station on a first carrier (e.g., an anchor carrier), and the UE may use a discontinuous reception (DRX) cycle on a second carrier. The DRX cycle may include scheduled on-durations during which the UE may monitor the second carrier for signaling from the base station. To reduce the power consumption at the UE associated with repeatedly monitoring scheduled on-durations, the base station may transmit wake-up signaling to the UE on the first carrier to identify the on-durations that include data from the base station. Accordingly, the UE may monitor these on-durations for the data and avoid monitoring other on-durations to limit power consumption.

Abstract: Load balancing is facilitated utilizing geographical location and mobility speed. An example method includes receiving, by a first cell device including a processor and associated with a first cell, from a device of devices, information indicative of whether the device has detected cell type information from a second cell device associated with a second cell, wherein at least a portion of the second cell is located within a first boundary of the first cell. The method also includes: determining, by the first cell device, a mobility characteristic of the device, wherein the devices comprise respective mobility characteristics; and selecting, by the first cell device, the device of the devices to associate with the second cell based on the mobility characteristic of the device.

Abstract: A first communication device generates and transmits a first physical layer (PHY) data unit as part of a hybrid automatic repeat request (HARQ) session, the first PHY data unit having a first plurality of media access control (MAC) protocol data units (MPDUs) including a first MPDU. The first communication device determines that a second communication device did not acknowledge successfully receiving the first MPDU. The first communication device generates and transmits a second PHY data unit as part of the HARQ session, the second PHY data unit having a second plurality of MPDUs, the second plurality of MPDUs including the first MPDU.

Abstract: The present invention is designed to provide a master information block (MIB) suitable for an NB-IoT communication system. A base station according to an embodiment of the present invention includes a generation section that generates a master information block (MIB) including parameters selected based on an operation mode during narrow band communication, and a transmission section that transmits the MIB.

Abstract: A diagnostic testing utility is used to perform single link diagnostics tests including an electrical loopback test, an optical loopback test, and a link traffic test. To perform the diagnostic tests, two ports at each end of a link are identified and configured as D_Ports and as such will be isolated from the fabric with no data traffic flowing through them. Advertisement frames may be sent at predetermined time intervals to transition the two ports to different states within the diagnostic test. After transitioning to the different states, the ports will then be used to send test frames to perform the diagnostic tests.

Abstract: Methods and apparatuses for a codebook for uplink MIMO in advanced wireless communication systems. A user equipment (UE) includes a processor and a transceiver operably connected to the processor. The transceiver is configured to transmit, to a base station (BS), a message reporting a coherence capability of the UE for an indication of a transmit precoding matrix indicator (TPMI) and a number of layers. The transceiver is configured to receive, from the BS, the indication of the TPMI and the number of layers via downlink control information (DCI) signaling. The transceiver is configured to transmit, to the BS, uplink (UL) data via a physical uplink shared channel (PUSCH) based on the received indication of the TPMI and the number of layers. A number of bits in the DCI signaling for the indication of the TPMI and the number of layers is determined by a coherence state that depends on the coherence capability reported by the UE.

Abstract: There are provided mechanisms for reporting channel coefficients to a wireless device. A method is performed by a network node. The method includes receiving reference signals from the wireless device. The method includes transmitting a first set of beam-formed reference signals. The first set of beam-formed reference signals reflects channel coefficients and is based on the received reference signals and the number of beams in the first set of beam-formed reference signals is less than the number of receive antennas in which the reference signals are received, thereby reporting the channel coefficients to the wireless device.

Abstract: The present disclosure relates to a pre-5th-Generation (5G) or 5G communication system to be provided for supporting higher data rates Beyond 4th-Generation (4G) communication system such as Long Term Evolution (LTE). An operating method for controlling interference between base stations in a wireless communication system includes determining at least one or more beam indexes of a first base station, receiving resource information of a second base station from the second base station, determining a frequency resource of the first base station, based on the at least one or more beam indexes of the first base station and the resource information of the second base station, and communicating with a user equipment, using information about the determined frequency resource of the first base station.

Abstract: Techniques are disclosed for a unified control plane in a nested cluster environment. In one example, an underlay orchestrator for a virtualized computing infrastructure is configured to provision, in an underlay cluster of one or more servers, an overlay cluster of one or more overlay nodes. Each of the overlay nodes is a workload of one of the servers and has a virtual network interface. Further, each server executes a virtual router and a virtual router agent for the virtual router for routing packets among virtual network interfaces of the overlay nodes executed by the server. A network controller is configured to configure virtual network sub-interfaces for workloads of the overlay nodes to enable communications among workloads executing in different overlay nodes. Each of the sub-interfaces is a virtual network sub-interface of one of the virtual network interfaces.

Abstract: A network controller is configured to receive a data packet from a core network for routing to a device in a wireless network. The controller may then select an antenna set from a plurality of antenna sets that are distributed across different base stations operable to transmit data packets to the destination device. The antenna set may be selected from the plurality of antenna sets based on a distribution pattern. For example, the distribution pattern may be a pseudo-randomly generated distribution pattern. The controller may then route the at least one data packet to the base station which the selected antenna set is implemented for transmission to the device. The antenna sets may be implemented on one base station, or implemented so that the antennas of an antenna set are distributed across multiple base stations. The antenna sets may also be configured to be of any number of antennas.

Abstract: The embodiments of the present disclosure provide a method for configuring scheduling signaling on an unlicensed carrier. The method includes: generating, by a base station, a carrier scheduling configuration message of the unlicensed carrier, the carrier scheduling configuration message including an uplink scheduling type identifier and a downlink scheduling type identifier; and sending, by the base station, Radio Resource Control (RRC) signaling to user equipment that carries the carrier scheduling configuration message. Scheduling flexibility and throughput of communication systems can be improved by implementing the present disclosure.

Abstract: The disclosure pertains to determining a channel width of a channel in a wireless communication network. An aspect is directed to a device (1200, 1300) configured to determine a quality indicator for each of a plurality of channels, determine, from the plurality of channels, a first subset of channels, the quality indicators of which meeting a first requirement, combine at least two adjacent channels of the first subset of channels to a combined channel, and perform a listen before talk, LBT, operation in the combined channel. Further aspects of the disclosure pertain to a further device for determining a channel width of a channel used in a wireless communication network, methods (1100, 1700), computer programs, and computer-readable recording media.

Abstract: For supporting a new radio access technology (new RAT, or NR), a frame structure for the new RAT may be configured. A network node configures a frame in which a first cyclic prefix (CP) is allocated to a first symbol in every 0.5 ms and a second CP is allocated to remaining symbols in every 0.5 ms. In this case, a length of the first CP is longer than a length of the second CP.

Abstract: A method and apparatus may be used to enable reception of a downlink (DL) shared channel in a cooperative multipoint transmission (CoMP). The method and apparatus may determine whether CoMP is applied to a transmission. The method and apparatus may acquire other CoMP related information. The method and apparatus may apply to non-transparent CoMP scenarios.

Abstract: A computer-implemented method includes: receiving, by a computing device, information regarding a range in which an Internet-of-Things (IoT) network is to be implemented; determining, by the computing device, respective detection scores for a plurality of IoT devices for each of a plurality of proposed congregation of IoT devices; determining, by the computing device, a minimum number of the plurality of IoT devices to cover the range by incorporating the detection scores into a covariance model; and outputting, by the computing device, information identifying the minimum number of the plurality of IoT devices for designing the IoT network.

Abstract: A method and network node for adaptation of contention windows in a multicarrier wireless communication system implementing a listen-before-talk protocol are disclosed. According to one aspect, a method includes determining at least one component carrier (CC), of multiple CCs to serve as a backoff channel. The method further includes performing a listen-before-talk procedure on the at least one CC serving as a backoff channel. The listen-before-talk procedure includes sensing for each backoff channel whether a clear channel exists during a backoff period drawn from a contention window (CW). The LBT procedure also includes deferring transmitting on a CC for which the sensing does not indicate that a clear channel exists. The LBT procedure also includes transmitting on a CC for which the sensing indicates a clear channel exists. The method also includes determining a size of the CW based on at least one transmission feedback value.

Abstract: A system and approach that may provide power to network switches of controllers in a failsafe manner. For instance, when a controller is receiving normal power, the controller may act as a power over Ethernet (POE) source that supplies power to its connected Ethernet devices as required. However, if power to a controller is lost, then Ethernet devices may switch to a powered device mode and use power from a neighboring device to keep active. Some power may be tapped for network switch operation from any network switch port receiving power from another device. This may allow communication to remain operational across multiple devices in a string of which some have lost a source of normal power.