The invention relates to a method for efficiently discarding data packets destined to a mobile station connected to both a master base station and a secondary base station. The master base station configures a secondary discard function in a lower layer of the secondary base station, based on the master discard function in the higher layer of the master base station. The master base station forwards the data packet from the higher layer to the lower of the secondary base station. The secondary discard function of the lower layer at the secondary base station discards the received data packet upon expiry of the secondary timer started by the lower layer upon reception of the data packet from the higher layer at the master base station.

According to an embodiment of the present disclosure, a method in a Distributed Unit, DU, of a network device is provided. The method includes: transmitting, to a Central Unit, CU, of the network device, a first message containing a request for resource coordination with another network device; and receiving, from the CU, a second message containing a response to the request from the other network device.

The present invention relates to the field of communications technologies, and in particular, to an RLC data packet offloading method and a base station, so as to solve a problem that performance of UE in a CA scenario of a non-ideal backhaul HetNet is affected due to a relatively long transmission delay between a macro eNodeB and a micro eNodeB. In embodiments of the present invention, a micro eNodeB may request a required RLC data packet before scheduling is performed; therefore, a macro eNodeB can send, to the micro eNodeB in advance, the RLC data packet required by the micro eNodeB, which reduces a transmission delay between the macro eNodeB and the micro eNodeB as much as possible, and improves receiving performance of UE.

A method for splitting end-to-end QoS requirement information, a terminal, and a network side device, the method comprising: a target device splits end-to-end QoS requirement information into PC5-segment QoS information and Uu-segment QoS information, the target device comprising a target UE and an access network device.

A wireless communication network to serve a wireless User Equipment (UE) with a wireless communication service over multiple wireless communication links. The wireless communication network comprises a primary access node, a first support access node, and a second support access node. The primary access node receives signal metrics for the support access nodes from the wireless UE, determines add thresholds for the support access nodes based on the amount of active UEs served by the primary access node, and converts the signal metrics for the support access nodes into add values for the support access nodes. When the add values are greater than the add thresholds, the primary access node signals the corresponding ones of the support access nodes to serve the wireless UE. The corresponding ones of the support access nodes exchange user data with the wireless UE.

This application provides a method includes: a first IAB node receives N data packets from a donor base station to a terminal device; the first IAB node determines a PDCP PDU SN of a first data packet in PDCP PDU SNs of the N data packets, where the PDCP PDU SN of the first data packet is a largest PDCP PDU SN in the PDCP PDU SNs of the N data packets, or the PDCP PDU SN of the first data packet is a largest PDCP PDU SN in consecutive PDCP PDU SNs starting from a smallest PDCP PDU SN in the PDCP PDU SNs that are of the N data packets and that are arranged in ascending order; and the first IAB node sends first information to the donor base station, where the first information includes a value of the PDCP PDU SN of the first data packet.

A method and network node (130; 110; 111) for managing uplink resources to be used by a wireless device 120. Cells (115, 116) for serving the wireless device (120) form at least one imbalance region (117) in which the wireless device (120) has the best quality in the downlink to a first cell (115) of a first type and in the uplink to a second cell (116) of a different, second type. The network node (130; 110; 111) identifies (301; 501) a situation associated with a risk for undesired decrease of transmit power used by the wireless device (120) when the wireless device (120) moves in the imbalance region (117). The network node (130; 110; 111) provides (302; 502), in response to the identification, an adjustment and/or record of a load in the uplink between the wireless device (120) and the first cell (115) and use of said adjusted and/or recorded load for determining one or more uplink resources to be used by the wireless device (120).

Certain aspects of the present disclosure relate to methods and apparatus for wireless communication, and more particularly, to methods and apparatus to enable a node to be aware of active services and context for a mobile device in order to determine the load balancing and admission control for the services. For example, in certain aspects, a mobile device for managing at least one data flow between a core network and the mobile device may determine whether at least one of the data flow or a service related to the data flow should be reported and send a report to a first node based on the determination. The report may identify at least one of the data flow or service and indicates a packet data network (PDN) connection or bearer associated with the service or data flow.

Embodiments of the present invention provide an access method, a base station, an access point and a user equipment. The access method includes: a base station sends a first message to an access point through a first communication interface, for requesting the access point to establish a second bearer with a user equipment UE, the second bearer being based on a second communication interface, wherein the first message carries an identifier of the UE and an identifier of an E-RAB; and the base station establishes a first bearer with the access point, the first bearer being based on the first communication interface, wherein the first bearer and the second bearer correspond to the E-RAB.

Disclosed is a data transmission method. The method includes that: when downlink data is transmitted, a master node shunts, on a Radio Link Control (RLC) sublayer, the downlink data to obtain shunted data packets, and sends the shunted data packets to shunting nodes; the shunting nodes process the shunted data packets, and send the processed data packets to a User Equipment (UE); and when uplink data is transmitted, the master node converges data packets sent from the shunting nodes and data packets sent from the UE, and sends the converged data packets to a core network. Also disclosed is a data transmission system. With embodiments of the disclosure, mobile communications system is able to provide an optimized service, a higher bandwidth and better performance.