The present disclosure relates to a 5th generation (5G) or pre-5G communication system for supporting a higher data transfer rate than 4th generation (4G) communication systems such as long term evolution (LTE). An operating method for a base station in a wireless communication method comprises a step for transmitting a first message to another base station, and a step for receiving a second message from the other base station, the first message comprising information indicating whether the base station supports at least one of an alternative quality of service (QoS) profile function and a QoS flow establishment queue function,

The present disclosure relates to a 5th generation (5G) or pre-5G communication system for supporting a higher data transfer rate than 4th generation (4G) communication systems such as long term evolution (LTE). An operating method for a base station in a wireless communication method comprises a step for transmitting a first message to another base station, and a step for receiving a second message from the other base station, the first message comprising information indicating whether the base station supports at least one of an alternative quality of service (QoS) profile function and a QoS flow establishment queue function,

The present technology relates to a wireless communication terminal and a wireless communication method that make it possible to execute coordinated transmission via a desired access point. The wireless communication terminal starts setting up the coordinated transmission in order to cause a plurality of wireless communication apparatuses to execute the coordinated transmission. The present technology is applicable to a wireless communication system.

A user equipment (UE) configured for dual connectivity with a split bearer configuration may transmit uplink data packets to one or both a master cell group (MCG) and a secondary cell group (SCG). The UE may transmit an uplink transmission from a packet data convergence protocol (PDCP) entity over one or both of a first radio link control (RLC) entity associated with the MCG and a second RLC entity associated with the SCG. The configuration including a transmit buffer threshold. The UE may receive, at the PDCP entity, an uplink switch start indication. The UE may activate the second RLC entity in response to receiving the uplink switch start indication. The UE may transmit a buffer status report according to a current transmit buffer level plus the transmit buffer threshold. Accordingly, the UE may communicate with the SCG based on the uplink switch start indication.

A relay control method according to the first aspect is a method used in a mobile communication system in which one or a plurality of relay nodes relay data from user equipment to a base station. The relay control method includes: predicting, by a first lower node, an estimate transmission data amount being an estimate amount of data to be transmitted within a certain period from the first lower node to a first upper node being an upper node of the first lower node; and transmitting, by the first lower node, data amount information indicating the estimate transmission data amount to the first upper node.

Disclosed is a wireless communication device including a communication circuit, a memory and a microprocessor coupled to the memory and the communication circuit. The communication circuit includes a radio frequency circuit and a first communication branch and a second communication branch sharing a frequency band and coupled to the radio frequency circuit. The memory is configured to store a network environment parameter index. The microprocessor is configured to detect a current state of a wireless network in real time based on the network environment parameter index to obtain current wireless network status data; obtain a time division multiplexing parameter according to an optimization goal and the current wireless network status data; and control the first communication branch and the second communication branch by using time division multiplexing according to the time division multiplexing parameter. Thus, spectrum and radio frequency resources can be optimally used.

The present disclosure relates to the field of wireless communication, and discloses a data transmission method and apparatus, a terminal device, and a storage medium. The method is applied in a terminal device including a Medium Access Control (MAC) layer and a physical layer. The method includes: delivering, by the physical layer, indication information to the MAC layer; adjusting, by the MAC layer based on the indication information, a priority of data at the MAC layer from prioritized to de-prioritized; and re-transmitting the data; or adjusting, by the MAC layer based on the indication information, a priority of a Scheduling Request (SR) at the MAC layer from prioritized to de-prioritized; and re-transmitting the SR.

The present invention discloses a wireless perception system energy and information transmission method of an unmanned aerial vehicle (UAV) swarm, comprising: building a wireless perception system architecture based on multi-UAV energy supply, wherein the system comprises a plurality of wireless powered sensors and a UAV swarm, and each sensor establishes connection with a UAV based on random access to realize network construction; designing energy and information transmission protocols in the swarm and between the swarm and the sensors, designing a joint optimization algorithm and solving optimal system configuration to obtain optimal transmission strategies. The present invention firstly proposes a joint optimization method of multi-network power allocation, time slot design and beam forming under the condition of multi-UAV autonomous collaborative energy supply, and also provides an efficient and reliable communication means for autonomous cooperative control of the UAV swarm.

Methods, systems, and devices for wireless communications are described. A device may manage an end-to-end delay budget for wireless communications. The communication device may receive semi-static control signaling indicating a packet delay requirement. The communication device may receive dynamic control signaling from a different device indicating a packet delay measurement for one or more of a packet or a group of packets associated with the wireless communication in one or more of a downlink or an uplink. The communication device may adjust a packet delay parameter to compensate a delay for one or more of the downlink or the uplink based on the packet delay requirement and the packet delay measurement, and may communicate in the downlink, the uplink, or both based on the adjusted packet delay parameter.

Aspects of the present disclosure relate to allocating workloads to vRANs via programmable switches at far-edge cloud datacenters. Traditionally, traffic allocation is handled by dedicated servers running load-balancing software. However, rerouting RAN traffic to such servers increases both energy and capital costs, degrades end-to-end performance, and requires additional physical space, all of which are undesirable or even infeasible for a RAN far-edge datacenter. Since switches are located in the path of data traffic, workflow policies can be designed to inspect packet headers of incoming traffic, evaluate real-time network information, determine available vRAN instances, and update the packet headers to steer the incoming traffic for processing. As network conditions change, the workflow policies enable the switch to dynamically redirect workloads to alternative vRANs for processing. As a result, RAN processing efficiency and fault tolerance are improved—even with changing network conditions and spikes in data traffic.