A wireless communication device includes a transceiver device and a data processing device. The transceiver device receives a frame from a wireless communication channel. The data processing device receives the frame and determines whether at least one of multiple predetermined frames has been received or is about to be received according to the frame. The data processing device enables a batch-frame indication mechanism when determining that said at least one of the multiple predetermined frames has been received or is about to be received. When the batch-frame indication mechanism is enabled, every time when one of the multiple predetermined frames is received, it is buffered in a reception queue instead of issuing a fetch indication, and when a number of predetermined frames buffered in the reception queue reaches a predetermined batch size, the data processing device issues the fetch indication to a back-end processing device.

A terminal according to one aspect of the present disclosure includes: a receiving section that receives configuration information on monitoring capability of a physical downlink control channel (PDCCH) for each serving cell; and a control section that controls derivation of at least one of a first parameter and a second parameter, the first parameter being used for restriction at carrier aggregation on a number of a span-based PDCCH candidates monitoring, the second parameter being used for restriction at carrier aggregation on a number of a slot-based PDCCH candidates monitoring. According to one aspect of the present disclosure, appropriate PDCCH monitoring can be performed even when a span is used.

A wireless communication network serves User Equipment (UEs) over a wireless network slice. A core user-plane in the slice exchanges user data with the UEs over a Radio Access Network (RAN). The core control-plane determines when the slice has a concentration of UEs that exceeds a threshold in a geographic area. When the slice has the UE concentration that exceeds the threshold in the geographic area, the core control-plane signals an edge user-plane to serve the UEs that use the wireless network slice in the geographic area. The edge user-plane exchanges additional user data over the RAN with the UEs that use the wireless network slice in the geographic area. The core control-plane may determine when the concentration of UEs moves toward another geographic area and proactively launch another edge user-plane to serve the UEs that will soon need the slice in the other geographic area.

A method for wireless communication performed by a sensing user equipment (UE) includes identifying resource availability during a sensing window. The method further includes receiving a request to share resource information with a transmitter UE. The method still further includes determining a sharing condition is satisfied. The method also includes sharing the resource availability with the transmitter UE based on satisfying the sharing condition.

The present disclosure provides an access control method performed at user equipment (UE), comprising: receiving, from a base station, multiple pieces of access control information corresponding to multiple network types; using the received multiple pieces of access control information to respectively perform an access control check for the multiple network types of networks; starting an access barring timer according to an access control check result; and if the access barring timer times out, informing an upper layer of the UE that barring of access is removed. The present disclosure also provides an access control configuration method for UE performed at a base station, corresponding UE, and a corresponding base station.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a first wireless communication device may iterate a value of a channel access counter (CAC) to a trigger value based at least in part on configuring the value of the CAC. In some aspects, the first wireless communication device may utilize a channel access mechanism to select a set of time-frequency resources for a transmission of a packet based at least in part on iterating the value of the CAC to the trigger value. In some aspects, the first wireless communication device may transmit the packet to a second wireless communication device via the set of time-frequency resources based at least in part on utilizing the channel access mechanism to select the set of time-frequency resources for the transmission. Numerous other aspects are provided.

A split radio access architecture comprises a packet processing node and one or more baseband processing nodes. The packet processing node receives, from a baseband processing node, first feedback corresponding to air interface congestion between the baseband processing node and a wireless device receiving packets from the baseband processing node. The packet processing node also receives, from the baseband processing node, second feedback corresponding to transport network congestion of a transport interface between the packet processing node and the baseband processing node. The packet processing node transmits user data to the baseband processing node based on the received first and second feedback.

Embodiments of this application provide a policy determining method and apparatus, and a system, and relate to the field of communication technologies, to formulate a first policy for a subarea more accurately. The solution includes: A first network element sends, to a data analytics network element, a first request for requesting network performance information. The first request includes information about a first area and information about a first time period. The first network element receives first network performance information in a second area from the data analytics network element. The first network element determines a first policy based on the first network performance information. In this solution, a subarea may be used as a granularity, and the first policy may be accurately determined based on first network performance information in the subarea.

A system and method for managing congestion in a multi-hop wireless network, employing congestion notification messages. The technology has three main components: a mechanism at the Medium Access (MAC) layer for determining when a given source or transit node is deemed congested; a mechanism at the Network Layer (NL) determining how to propagate this information to applications, including suitably combining overload indications received from neighbors; and a mechanism at the Transport Layer (TL) of each source of traffic for determining when a source is generating excessive traffic, and combining it with Medium Access Control (MAC)-based overload indication from downstream nodes, thus providing a multi-layer approach to traffic throttling.

Methods, computing platforms, storage media, and systems for providing congestion control in Road Side Unit message (“RSU message”) scheduling. One aspect of the present disclosure relates to a method for providing congestion control in RSU message scheduling. Various aspects include measuring a channel busy ratio by a PC5 access layer of a Road Side Unit, comparing the measured channel busy ratio to one or more thresholds, and generating and transmitting RSU messages at a rate determined based upon whether the measured channel busy ratio equals or exceeds the one or more thresholds.