This document discloses a solution for selecting a transmission direction in a cell. A method comprises: determining, by a controller associated with a cell of a cellular communication system, a traffic asymmetry metric for the cell, the traffic asymmetry metric representing asymmetry between uplink and downlink traffic in the cell; comparing, by the controller, the traffic asymmetry metric with a threshold; upon determining, by the controller on the basis of the comparison, that the traffic asymmetry metric is one of greater and lower than the threshold, selecting a first transmission direction for a time interval; upon determining, by the controller on the basis of the comparison, that the traffic asymmetry metric is the other one of greater and lower than the threshold, selecting for the time interval a second transmission direction different from the first transmission direction, wherein the second transmission direction is a nominal transmission direction determined as common to a cell cluster comprising the cell and a set of neighboring cells, and wherein the controller determines the nominal transmission direction on the basis of traffic condition metrics acquired for the cell and for the set of neighboring cells; and causing data communication to the selected transmission direction in the cell during the time interval.

A gateway, for use with a first and a second access point device (APD), scans channels within a spectrum of channels. The gateway includes a delegating component, a communication component, and a load balancing component. The delegating component is operable to instruct each APD to monitor for presence of a signal on any one of a respective first or second set of channels within the spectrum. The communication component is operable to receive from the first APD a channel-in-use signal associated with an in-use channel of the first set of channels; transmit a notification signal to the second APD based on the channel-in-use signal; transmit the instruction to the first APD and the second APD; and receive a communication signal from either APD as a result of the transmission. The load balancing component is operable to determine a communication volume on each of the first set of channels, and to generate an instruction to instruct the first and second APDs to not use the in-use channel.

Mitigating channel congestion, or crowding, that degrades the performance capabilities of a venue-provided access point, or hotspot, can include identifying, with a mobile communication device, the venue-provided access point. Additionally, mitigating channel congestion can also include establishing a mobile hotspot with the mobile communication device. The mobile communication device can establish the mobile hotspot on a channel different from a channel used by the venue-provided access point. Mitigating channel congestion can also include reducing a signal radius of the mobile communication device by reducing transmission power of the mobile communication device.

The art relates to a communication method and device for a wireless communication network and a wireless communication network. In the communication method, to one cell cluster in at least one cell cluster included in the wireless communication network, an Uplink-downlink ratio configuration scheme of the cell cluster during the next ratio configuration adjusting period is determined based on un-allocatable prediction amount for un-allocatable services of each cell in the cell cluster, and allocatable prediction amount for the services, which can be allocated to other cell(s), of each cell in the cell cluster, thus utilization efficiency of communication resource is optimized, and the cells in the cell cluster have the same communication frequency and Uplink-downlink ratio configuration scheme. According to the embodiments of the invention, the utilization efficiency of communication resource can be improved.

A system, such as a gateway, is provided for use with a first access point device and a second access point device to scan channels within a spectrum of channels. The system includes; a delegating component that is operable to instruct the first access point device to monitor for a presence of a signal on any one of a first set of channels within a spectrum of channels and to instruct the second access point device to monitor for a presence of a signal on any one of a second set of channels within a spectrum of channels; a communication component operable to receive a channel-in-use signal from the first access point device and to transmit a notification signal to the second access point device based on the channel-in-use signal, the channel-in-use signal being associated with an in-use channel of the first set of channels within the spectrum of channels, the communication component is additionally operable to transmit the instruction to the first access point device and the second access point device, the communication component is further operable to receive a communication signal from one of the first access point device and the second access point device as a result of the transmission of the instruction; and a load balancing component operable to determine a communication volume on each of the first set of channels within the spectrum of channels, and to generate an instruction to instruct the first access point device and the second access point device to not use the in-use channel.

Embodiments of the present disclosure provide methods and apparatuses for quality of service management. A method implemented at a first device may comprise determining one or more sub latency targets corresponding to one or more intermediate devices along an uplink or downlink route between a second device and a third device based on an uplink or downlink route total latency target and an uplink or downlink latency of one hop along the uplink or downlink route of each of the one or more intermediate devices; and sending the one or more sub latency targets to the one or more intermediate devices, wherein a sum of the one or more sub latency targets is smaller than or equal to the uplink or downlink total latency target.

The performance and ease of management of wireless communications environments is improved by a mechanism that enables access points (APs) to perform automatic channel selection. A wireless network can therefore include multiple APs, each of which will automatically choose a channel such that channel usage is optimized. Furthermore, APs can perform automatic power adjustment so that multiple APs can operate on the same channel while minimizing interference with each other. Wireless stations are load balanced across APs so that user bandwidth is optimized. A movement detection scheme provides seamless roaming of stations between APs.

The performance and ease of management of wireless communications environments is improved by a mechanism that enables access points (APs) to perform automatic channel selection. A wireless network can therefore include multiple APs, each of which will automatically choose a channel such that channel usage is optimized. Furthermore, APs can perform automatic power adjustment so that multiple APs can operate on the same channel while minimizing interference with each other. Wireless stations are load balanced across APs so that user bandwidth is optimized. A movement detection scheme provides seamless roaming of stations between APs.

A load balancing method which includes a first radio access network node that receives load information of a first load type of a second radio access network node, where the first load type includes any one or more of the following: a network slice load, V2X load, and SUL load; and the first radio access network node obtains the load information of the first load type, so that load balancing can be performed based on a load status of a network slice, a load status of a V2X service, or a load status of a UL/SUL.

The system obtains an acyclic graph including multiple nodes and edges. An edge indicates a parent node and a child node to be included in a weave indicating a linear order of the multiple nodes. The parent node occurs before the child node in the weave. The acyclic graph includes a branch node having a first and a second child node that do not have a parent-child relationship indicating the weave. The system orders the multiple nodes in the acyclic graph by ordering a portion of the multiple nodes according to a portion of the multiple edges. The system orders the first child node and the second child node by obtaining a first priority associated with the first child node and a second priority associated with the second child node and, based on the first and second priority, creating the weave by ordering the first and second child node.