Abstract: Apparatus, methods, and computer-readable media for facilitating simplified switching at an RU are disclosed herein. An example method for wireless communication at an RU includes transmitting, to a DU, capability information indicating support of endpoint groups, each endpoint group associated with a respective set of RU endpoints. The example method also includes receiving an eAxC message from the DU based on the capability information, the eAxC message including a DU port identifier, a band sector identifier, a component carrier identifier, and an RU port identifier. The example method also includes using a first portion of the RU port identifier to identify an endpoint group, the respective set of RU endpoints of the endpoint group associated with a set of characteristics. Additionally, the example method includes using a second portion of the RU port identifier to index the eAxC message to an RU endpoint of the endpoint group.

Abstract: A communication system includes a central cloud server that causes each of a plurality of edge devices to initiate a discovery process. The central cloud server obtains a plurality of sensed parameters from each edge device based on the discovery process, where the plurality of sensed parameters are associated with donor antenna array and one or more relay antenna arrays of each edge device. The central cloud server determines a plurality of path setup parameters specific for each edge device. The plurality of path setup parameters determined specifically for each edge device are communicated to each corresponding edge device. The central cloud server causes the plurality of edge devices to form a mesh network such that a spatial coverage of a first radio access network node is increased to serve one or more remote user equipment via the mesh network with a throughput rate greater than a threshold.

Abstract: Disclosed in the present application is a method by which a terminal determines a communication technique in a wireless communication system. Particularly, the communication technique determining method comprises the steps of: transmitting/receiving a signal through a first channel by using a first communication technique; confirming whether a second communication technique using a second channel is used in a monitoring gap; and transmitting/receiving a signal through the second channel by using the first communication technique, if it is confirmed that the second communication technique using the second channel is not used, wherein the use of the first communication technique through the second channel is prohibited in the monitoring gap.

Abstract: A system and method for implementing Transport Layer Security (TLS) Routing Agent in an Internet Protocol Exchange (IPX) network for 5G core roaming. Transmission Control Protocol (TCP) connections are established between the TLS Routing Agent and consumer Security Edge Protection Proxy (cSEPP) and producer Security Edge Protection Proxy (pSEPP). TLS Routing Agent receives HTTP/2 CONNECT request from cSEPP. The TLS Routing Agent routes subsequent TLS handshake and HTTP/2 application messages to producer-SEPP transparently, so that the end-to-end TLS security is maintained. The TLS Routing Agent enables message firewall to protect mobile operator's SEPP. The TLS Routing Agent applies policy routing to route HTTP/2 message intelligently across the IPX network and improves TCP performance by dividing the long Round-Trip-Time between TCP end points into shorter segments.

Abstract: The embodiments herein relate to a method performed by a SMF, for handling local breakout of traffic. The SMF receives, from a PCF, policy information indicating traffic that should be routed via a second UPF to a second DN. The SMF provides, to a first UPF, a first traffic detection filter for detecting the traffic indicated in the received policy information. The SMF detects that there is traffic matching the first traffic detection filter. The SMF sets up, according to the policy information, a local breakout to the second UPF when the matching traffic has been detected. The setting-up comprises setting-up the second UPF.

Abstract: An extender device for communication in a multihop network comprises: a first wireless transceiver operable in electronic communication with a border router; a second wireless transceiver operable in electronic communication with one or more network attachable devices; and a routing component operable to cause said extender device to assume routing control of messages received at said first wireless transceiver for one or more said network attachable devices operable to handle messages having a specified identifier.

Abstract: A system and method of Random-Access Response, RAR, messaging when a base station employs narrow beamforming. Multiple RAR messages are successively transmitted from the base station to a User Equipment, UE, before any response to a RAR message is received from the UE. Thus, despite any calibration mismatch between Uplink, UL, and Downlink, DL, beams in the beamformed system, a RAR message is not only received by the UE, but is received over the most-suitable DL beam for that UE. Each RAR message may contain a message-specific scheduling-delay indicator in the UL grant carried in the RAR message to provide an adjustable time delay for the UE's uplink transmission scheduled by the UL grant. Multiple RAR transmissions can schedule a single UL transmission at a specific time instance or different UL transmissions at different time intervals. The UE may report to the base station the best DL RAR transmission detected by the UE.

Abstract: A method of controlling communications within a wireless communications network is provided. The communications network comprises a plurality of infrastructure equipment each being configured to communicate with one or more others of the infrastructure equipment via a backhaul communications link, one or more of the infrastructure equipment each being configured to communicate with one or more communications devices via a wireless access interface.

Abstract: Embodiments of the present disclosure provide a backhaul path switching method, a wireless relay, a network-side node and a terminal. In the embodiments of the present disclosure, a second backhaul path is pre-established, a backhaul path is switched in the case that a radio link fails or signal quality of a related wireless relay does not meet requirements.

Abstract: Examples of the present disclosure provide a method for setting up a route path, a device and a computer-readable storage medium. The method may include: establishing a neighbor list; wherein, the neighbor list comprises neighbor nodes of the node and position information of the neighbor nodes; in response to receiving a routing request (RREQ) message from a previous hop node, recording a source Internet Protocol (IP) address of a source node contained in the RREQ message as a destination IP address in a routing table established in the node; recording the previous hop node as a next hop node corresponding to the destination IP address in the routing table; selecting a pre-determined number of nodes from the neighbor list as next hop nodes of the RREQ message according to the position information of the neighbor nodes; and sending the RREQ message to the next hop nodes.

Abstract: An in-vehicle network system includes: an upper device; a first intermediate device that is connected to the upper device directly or via at least one device and is configured to communicate with the upper device using a first communication system; a second intermediate device that is connected to the upper device directly or via at least one device and is configured to communicate with the upper device using a second communication system; and a first lower device that is directly connected to the first intermediate device and is configured to communicate with the first intermediate device using the first communication system, and that is directly connected to the second intermediate device and is configured to communicate with the second intermediate device using the second communication system.

Abstract: Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a base station (BS) may determine, for a user equipment (UE) operating in a mobility state, route information. The BS may transmit, to the UE, information identifying a set of beams based at least in part on the route information. The UE may perform a set of neighbor cell measurements, in connection with movement along the predicted route, using the set of beams. Numerous other aspects are provided.

Abstract: A solution for establishing a data traffic session for a user equipment (UE) on a network (e.g., a 4G or 5G cellular network) includes: receiving, by a session management node, from the UE, a request to set up the data traffic session; determining an availability or unavailability of a first packet routing node to handle UE data traffic, which includes receiving an indication of the availability or unavailability of the first packet routing node from a network repository; based at least on determining that the first packet routing node is available to handle UE data traffic, establishing the data traffic session with the first packet routing node; and based at least on determining that the first packet routing node is unavailable to handle UE data traffic, establishing the data traffic session with an available alternate packet routing node.

Abstract: There is disclosed a method of operating a network node in a Radio Access Network. The method includes transmitting a downlink control information message, the downlink control information message having a slot allocation indication and a symbol allocation indication. The slot allocation indication indicates a slot aggregation having a plurality of slots being allocated for communication to at least one user equipment, wherein each slot com includes prises a plurality of symbols. The symbol allocation indication indicates allocation of symbols to at least one channel according to an allocation pattern for two or more of the plurality of slots. The disclosure also pertains to related methods and devices.

Abstract: There is provided a method in a radio communication network providing a service for a plurality of devices, the method comprising: determining a service outage probability for a device that is going to move to a sub-area of a coverage area of the network, the service outage probability associated with said sub-area; in response to determining that the service outage probability exceeds a threshold, requesting a measurement device to move to said sub-area and to perform one or more radio frequency measurements; determining whether the service outage probability exceeds another threshold based at least on the requested one or more radio frequency measurements; and triggering at least one action if the service outage probability exceeds said another threshold.

Abstract: Apparatuses, methods and infrastructures for interacting with SNDs and SLANs are described.

Abstract: Techniques are disclosed for providing a distributed customer premises equipment (CPE) comprising several devices. A computer system executes a control plane subsystem that sends network control packets using one or more network interfaces for controlling network data packet forwarding operations performed by devices. The network control packets includes a first set of network control packets sent to a first device located at a second location and a second set of network control packets sent to a second device located at a third location.

Abstract: An example method comprises receiving, by a first PHY of a first transceiver, a timing packet, timestamping, by the first transceiver, the timing packet and providing the timing packet to a first intermediate node, determining a first offset between the first intermediate node and the first transceiver, updating a first field within the timing packet with the first offset between the first intermediate node and the first transceiver, the offset being in the direction of the second transceiver, receiving the timing packet by a second transceiver, the timing packet including the first field, information within the first field being at least based on the first offset, determining a second offset between the second transceiver and an intermediate node that provided the timing packet to the second transceiver and correcting a time of the second transceiver based on the information within the first field and the second offset.

Abstract: A wireless transmit receive unit (WTRU) and a method performed by the WTRU for receiving radio resource control (RRC) signaling including information indicating a primary cell and at least one non-primary cell, receiving a single message with scheduling information indicating an allocation of uplink resources and a hybrid automatic repeat request (HARQ) process ID, wherein the WTRU has one or more HARQ processes and uplink transmissions by the WTRU utilize asynchronous HARQ, and transmitting to at least the non-primary cell an uplink transmission using a HARQ process indicated by the HARQ process ID and the allocation of uplink resources.

Abstract: A method and a mesh node (200) for enabling communication of packets in a wireless mesh network with multiple mesh nodes. When receiving (2:2) an original advertisement message with a Bloom filter initiated by an original gateway (204), it is detected that a predetermined maximum fill rate is reached in the received Bloom filter. The mesh node (200) starts to act as an intermediate gateway and creates a new advertisement message (2:3) comprising a new initiated Bloom filter with a reduced fill rate. The new advertisement message is then transmitted (2:4) with the new Bloom filter while indicating that the new advertisement message originates from said original gateway (204).