In a wireless local area network system, a station (STA) can transmit a PPDU including frame drop information. The frame drop information can include information related to whether a frame drop caused by time latency has occurred in the STA.

A processing method of direct communication, a processing device of direct communication, a relay terminal and a remote terminal are provided. The method includes: receiving a direct communication request message sent by a remote terminal, where the direct communication request message includes: a flow identification of a first QoS flow requested to be established and a QoS parameter of the first QoS flow; the first QoS flow is a QoS flow on a direct communication interface between the remote terminal and the relay terminal; and sending a direct communication response message to the remote terminal, where the direct communication response message is configured to indicate that an establishment of the first QoS flow is finished.

The present disclosure provides a server, a remote control device, and a remote control method for an automatic (or autonomous) driving vehicle. The method may include: after receiving a remote control request of an automatic driving vehicle, acquiring a target wireless channel of a target wireless network with the shortest communication delay from a plurality of candidate wireless channels of a plurality of candidate wireless networks in combination with the current geographic location of the automatic driving vehicle, and transmitting a corresponding control instruction to the automatic driving vehicle through the target wireless channel of the target wireless network.

According to certain embodiments, a method is provided by a distribution node for location aware scheduling. The method includes determining information about a condition associated with a packet. At least one Quality of Service, QoS, parameter is adjusted based on the information about the condition associated with the packet. The at least one QoS parameter is used to schedule the packet for transmission to a receiver based on the at least one adjusted QoS parameter.

A device may determine a set of parameters related to a transmission of a packet. For example, a device may determine a transmission range indication for the packet, a Quality-of-Service (QoS) of the packet, or a combination thereof. The device may then determine a resource exclusion parameter related to the transmission of the packet based in part on the set of parameters. Following the determination, the device may transmit, to one or more other devices in a wireless communications system, control signaling including the resource exclusion parameter.

Systems, devices, and techniques described herein relate to intelligently allocating network resources to Quality of Service (QoS)-sensitive data traffic. An example method includes identifying a request to deliver QoS-sensitive services to a User Equipment (UE) over at least one delivery network. The at least one delivery network may include at least one reserved resource and at least one pooled resource. The QoS-sensitive services are determined to be delivered over the at least one pooled resource. In addition, delivery of the QoS-sensitive services is caused over the at least one pooled resource.

A method and apparatus of a device that selects a periodic resource associated with a pre-empted resource on a wireless link between a first user equipment and one or more second user equipment is described. In exemplary embodiments, the device detects a pre-empted resource that is one of a plurality of resources reserved for a first UE on a wireless link between the first UE and a second UE. In addition, the device may determine a new resource for the pre-empted resource. The device may further determine a periodic resource for the plurality of reserved resources.

In a band sharing communication system in which there are a primary system and a secondary system in descending order of priority of communication, the systems share frequency bands, and a base station or a line control device performs allocation of a requested band of a terminal station of each system, the base station or the line control device including: occupied band setting means for setting a primary occupied band and a secondary occupied band adjacent to the primary occupied band; band allocation means for allocating a vacant band of the primary occupied band with respect to a requested band of a primary terminal station and allocating a vacant band of the secondary occupied band with respect to a requested band of a secondary terminal station; and band transferring means for, when there is no vacant band in the primary occupied band with respect to a requested band of the primary terminal station, transferring a band of the secondary occupied band from the secondary occupied band to the primary occupied band and allocating the band to the primary terminal station, said band being adjacent to the primary occupied band and equivalent to the requested band. The secondary terminal station is configured to, when the secondary terminal station is performing communication in the band equivalent to the requested band and being transferred from the secondary occupied band to the primary occupied band and detects degradation in communication quality due to interference with the primary terminal station, suspend said band and provide the band to the primary terminal station.

When a first sidelink channel state information CSI report is triggered, a first terminal obtains a first sidelink resource configured by a base station for the first terminal, where the first sidelink resource can be used to transmit the sidelink CSI report. The first terminal sends the first sidelink CSI report to a second terminal on the first sidelink resource, where the first sidelink CSI report is used to feed back CSI of a sidelink between the first terminal and the second terminal.

A method of operating a terminal device for transmitting a first amount of data, the method comprising receiving an indication of an allocation of communications resources, the allocated communications resources sufficient for transmitting a second amount of data, the second amount of data greater than or equal to the first amount of the data, selecting from a plurality of permitted TBS values a transport block size, TBS, for the transmission of the first amount of data, based on the first amount, determining communications resources for transmitting the first amount of the data based on the selected TBS and the allocated communications resources, and transmitting the first amount of the data using the determined communications resources.