Provided are a transmission parameter determination method, a terminal device and a network device. The method comprises: the terminal device determines a first transmission parameter according to the channel busy ratio (CBR) and the priority of service to be transmitted; and the terminal device sends the service to be transmitted using the first transmission parameter, and further comprises: the terminal device acquires at least one proportion coefficient, the at least one proportion coefficient being configured by a network device or pre-configured in the terminal device, wherein the operation of determining the first transmission parameter according to the CBR and the priority of the service to be transmitted comprises: the terminal device determines a second transmission parameter according to the CBR and the priority of the service to be transmitted, and processes the second transmission parameter using the at least one proportion coefficient to obtain the first transmission parameter.

Aspects of the subject disclosure may include, for example, obtaining data relating to a user equipment communicatively coupled to a first network node, the data including information regarding a data buffer associated with the user equipment, obtaining node information relating to a second network node, the node information identifying available network resources of the second network node and a coverage range of the second network node, determining, based on the information regarding the data buffer, that a status of the data buffer satisfies a condition, determining that the first network node has insufficient network resources to satisfy a network resource demand of the user equipment based on the determining that the status of the data buffer satisfies the condition, and selectively activating the second network node, based on the available network resources of the second network node and the coverage range of the second network node. Other embodiments are disclosed.

Systems, methods, and software of managing bandwidth allocated to User Equipment (UE). In one embodiment, a bandwidth management system collects cell load information for a plurality of cells within a Radio Access Network (RAN), and processes the cell load information to determine a cell load status for each of the cells. The system performs bandwidth throttling for the UE by determining a location of the UE, identifying the cell load status for one or more cells in a region of the RAN corresponding with the location of the UE, determining whether the region of the RAN is overloaded based on the cell load status, and controlling a downgrade of bandwidth allocated to the UE in the RAN responsive to a determination that the region is overloaded.

The disclosure relates to a fifth generation (5G) or sixth generation (6G) communication system. A method performed by a first integrated access and backhaul (IAB) node which is a F1-terminating IAB donor node in a wireless communication system is provided. The method includes receiving, from a second IAB node which is a non-F1-terminating IAB donor node, a first message including backhaul (BH) related information for at least one IAB node of a non-F1-terminating topology associated with the second IAB node and transmitting, to a third IAB node which is an IAB node connected with the first IAB node and the second IAB node, a second message including configuration information for the third IAB node.

The technology described herein reduces control-plane overloading by transferring UEs from the overloaded control plane to another available control plane. At a high level, the technology identifies when a control plane is overloaded, identifies other available control planes in a geographic area served by the overloaded control plane, and then identifies UEs for transfer using one or more criteria. Initially, a measure of control-plane performance for a control plane is received. Next, a determination is made that the control plane is overloaded by comparing the measure of control-plane performance to an overload threshold. When an overload condition exists for a control plane, then UEs with existing communication sessions using the control plane are identified for transfer.

A gateway apparatus connected to another different network. The gateway apparatus includes: extraction unit that extracts first information set in a first packet(s) that has been received from a relay apparatus relaying a packet(s) between the gateway apparatus and a terminal or from a node arranged in the different network; setting unit that sets, based on the first information, second information in a second packet(s) in a protocol(s) in a layer(s) different from a layer(s) of a protocol(s) of the first packet(s); and forwarding unit that forwards the second packet(s) in which the second information is set to the node or to the relay apparatus.

This disclosure is directed to allocation of one or more radio bands to a user equipment (UE) for establishing a radio link with a radio node (e.g., eNodeB or gNodeB). The radio bands may include a shared band, such as citizens band radio service (CBRS), a primary licensed band, such as the B66 band, and/or an unlicensed band, such as B46 band. A radio communications system may consider a variety of parameters associated with the distance of a UE from a radio node, signal strength of a signal from the UE, the services requested by the UE, and/or spectral availability of the each of the radio bands to determine which radio band(s) to allocate to the UE. In some cases, the radio band allocated to a UE may be dynamically changed by the radio communications system as conditions related to the UE and/or the mobile network change.

A wireless communication network delivers a video-conferencing service from a video-conferencing system to wireless User Equipment (UEs) over a wireless network core and a Radio Access Network (RAN). The wireless network core monitors performance of video-conferencing functions in the video-conferencing system and prioritizes the video-conferencing functions based on their performance. The wireless network core transfers a video-conferencing function list to the RAN that prioritizes the video-conferencing functions by their performance. The RAN wirelessly transfers the video-conferencing function list to the wireless UEs. The RAN wirelessly exchanges video-conference signaling between the wireless UEs and the wireless network core. The wireless network core exchanges the video-conference signaling between the RAN and the video-conferencing functions. Individual wireless UEs select their individual video-conferencing functions based on the video-conferencing function list that prioritizes the video-conferencing functions by their performance.

Systems and methods for managing telecommunication traffic for a wireless communication network associated with multiple coverage areas (“cells”) are disclosed. The system may detect congested cells of the wireless communication network, identify suitable neighboring cells for offloading traffic from the congested cells, and implementing handovers from congested cells to suitable neighbor cells to balance the wireless communication network traffic.

Systems and methods of providing RAT co-existence and congestion control in V2V communications are generally described. A vUE detects specific non-LTE RAT transmissions in a listening period of a PSSCH or PSSCH, determines whether a metric has been met and reselects to a non-overloaded channel to communicate with other vUEs or the eNB. The manner of reselection is dependent on the RAT specific or V2X service priorities of the channels, as well as whether the channels are V2V service dependent.