Various embodiments comprise systems, methods, mechanisms, and apparatus providing a traffic management function suitable for use at an intermediate Transmission Control Protocol (TCP) node (e.g., a cable modem) through which TCP uplink (UL) and downlink (DL) session traffic flows via respective linked UL and DL buffers is configured to manage ACK/NACK message insertion into the DL buffer to provide accelerated TCP UL packet size increases to so as to rapidly increase TCP UL data flow through the intermediate network node, and to provide constrained TCP UL packet size so as to rapidly decrease TCP UL data flow (apply backpressure) so as to avoid a buffer overflow condition.

The present disclosure provides a method in a terminal device having Dual Connectivity, DC, with a master network device and a secondary network device. The method includes: determining, for a split bearer, to split data to be transmitted to the master network device and the secondary network device based at least on a channel occupancy and/or Listen Before Talk, LBT, statistics associated with a connection to the secondary network device; and splitting the data for transmitting to the master network device and the secondary network device over the split bearer.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive information indicating a timer value of a timer associated with discarding a packet data convergence protocol (PDCP) service data unit (SDU). The UE may determine that a timer modification condition is satisfied. The UE may modify the timer value based at least in part on the determination that the timer modification condition is satisfied. The UE may transmit a communication using the modified timer value. Numerous other aspects are provided.

A transport path group for uplink transmission over a fronthaul interface. The transport path group may include (i) an address of a first source port of a radio unit (RU), (ii) an address of a first destination port of a distributed unit (DU), and (iii) an address of a second source port of the RU, an address of a second destination port of the DU, and/or a flow identifier (e.g., a virtualized local area network (VLAN)). A request for user data conveyed by the DU and received by the RU may identify the transport path group. The RU may use the fronthaul interface to convey to the DU first and second portions of the requested user data over first and second different paths from the RU to the DU. The RU may employ load balancing parameters to convey the first and second portions of the requested user data.

A method for restricting multi-connectivity functionality of a user equipment (UE) includes: storing a mapping table on a memory of the UE, wherein the mapping table provides assignment information about a respective single access mode assigned to a service requestable by the UE, wherein the respective single access mode is one of multiple access modes; receiving service information about a requested service via a network interface of the UE; comparing, by a process of the UE, the service information to entries of the mapping table, and selecting a single access mode assigned to the requested service; wherein the multi-connectivity functionality of the UE is restricted by: a bypass entity redirecting data traffic associated with the requested service directly to the selected single access mode; or a multipath scheduler scheduling data traffic associated with the requested service to a communication link that corresponds to the selected single access mode.

This disclosure describes systems, devices, and computer-implemented methods that facilitate the simultaneous transmission of subsets of user plane data to a telecommunications network via two or more uplink transmission paths. More specifically, a mobile device may detect user plane data within a buffer pool and in doing so, transmit a resource allocation request for the uplink transmission of the user plane data. In response, the mobile device may receive a set of control plane data associated with the uplink transmission via two or more uplink transmission paths. The mobile device may simultaneously transmit subsets of user plane data to the telecommunications network via multiple base station nodes, based at least in part on the control plane data.

A method and system for controlling uplink communication from a user equipment device (UE) that has at least two co-existing air-interface connections including a first air-interface connection with a first access node and a second air-interface connection with a second access node. An example method includes comparing a level of antenna pattern efficiency associated with the first air-interface connection with a level of antenna pattern efficiency associated with the second air-interface connection and, based at least on the comparing, configuring an uplink split ratio defining a distribution of uplink user-plane data flow of the UE between at least the first air-interface connection and the second air-interface connection. In an example implementation, this could involve configuring one of the air-interface connections as a primary uplink path to which the UE restricts its uplink communication unless and until a trigger occurs for transitioning the UE to operate in an split-uplink mode.

A method and system for controlling uplink communication from a user equipment device (UE) that has at least two co-existing air-interface connections including a first air-interface connection with a first access node and a second air-interface connection with a second access node. An example method includes comparing a level of uplink backhaul congestion of the first access node with a level of uplink backhaul congestion of the second access node and, based at least on the comparing, configuring an uplink split ratio defining a distribution of uplink user-plane data flow of the UE between at least the first air-interface connection and the second air-interface connection. In an example implementation, this could involve configuring one of the air-interface connections as a primary uplink path to which the UE restricts its uplink communication unless and until a trigger occurs for transitioning the UE to operate in an split-uplink mode.

A data transmission method and UE. The method includes: performing a target operation on first uplink data according to first information, where the target operation includes: in a case that the first 5 information is used to indicate that a first path is capable of transmitting uplink data, transmitting the first uplink data on the first path, and/or in a case that the first information is used to indicate that a second path is incapable of transmitting target uplink data, and that the first uplink data belongs to the target uplink data, skipping transmitting the first uplink data on the second path; and the first path is 10 a source path between the UE and a source cell, the second path is a target path between the UE and a target cell; or, the first path is the target path, and the second path is the source path.

There is provided a method for an apparatus for a network function, the apparatus for the network function, and a computer program for the apparatus, that causes the apparatus to: receive an indication that a first user equipment and/or a first user plane function configured to transmit first user traffic is associated with a first replication handling function, the first replication handling function being configurable to coordinate at least one replication-based redundancy mechanism performed on at least part of said first user traffic; determine a first set of replication rules for use by the first replication handling function determining when the at least one replication-based redundancy mechanism is performed on at least part of said first user traffic; and cause the first set of replication rules to be provided to the first replication handling function.