A first network node is arranged to communicate with a second network node. The first and second network nodes are connected by a first path and a second path. The first path uses a first communications network and the second path uses a second communications network. The first network node has a first mode and a second mode of operation, such that in a first mode traffic between the first and second network nodes is transmitted over the first path and not the second path, and in a second mode traffic between the first and second network nodes is transmitted over the first path and the second path. The network node comprises a mode selector arranged to select the second mode of operation when the demanded amount of traffic between the first and second network nodes exceeds a threshold value for a period of time.

A domain name access method and a device are described. As described herein, a domain name server (DNS) server performs resolution on a domain name requested by the terminal device. The DNS server may then send an internet protocol (IP) address of an application server obtained through the resolution and use condition information to the terminal device. With this, communication efficiency of the terminal device can be improved, and waste of transmission resources in a communications system is also avoided.

Logical Channel Prioritization (LCP) may be enhanced by accounting for Quality of Service (QoS) attributes of single hop and multi-hop paths. QoS attributes may be communicated as a QoS budget comprising a number of attributes, or as a single composite QoS “resistance” factor that quantifies the compounded impact of number of hops, latency, load conditions, and the like. The QoS budget or resistance may dynamically adjusted, and may be used by LCP to provide differentiated uplink resource allocation to data of the bearer or logical channel subject to different transmission paths between the transmitter and the receiver, for example. QoS budget and resistance information may be used to, e.g., enhance Buffer Status Report (BSR) and Scheduling Request (SR) operations.

The embodiments of the present disclosure provide a method for supporting quality of service of time-sensitive communication and a communication device. The method includes: obtaining first information, where the first information includes at least one of the following: transfer configuration information of a time-sensitive data stream, or bridge capability information; and performing a first operation according to the first information.

According to an aspect, a communication device includes a communicator configured to perform communication with a base station and a plurality of access points having narrower communication ranges than the base station, a first acquirer configured to acquire vehicle information from equipment mounted in a vehicle, a second acquirer configured to acquire information about communication quality for each of the plurality of access points, a third acquirer configured to acquire a communication requirement for each piece of the vehicle information acquired by the first acquirer, and a selector configured to select an access point that transmits the vehicle information acquired by the first acquirer on the basis of the information about the communication quality acquired by the second acquirer and the communication requirement acquired by the third acquirer.

Systems and methods are disclosed herein that enable Time Sensitive Networking (TSN) network or Deterministic Networking (DetNet) network replication function fallback. In some embodiments, a method comprises, at a primary replication function, obtaining a packet in a particular stream, obtaining a sequence number for the packet, generating M copies of the packet each comprising the sequence number, transmitting the M copies, and providing, to a redundancy controller, the sequence number or a next sequence number of a next packet to be transmitted for the particular stream. The method further comprises, at the redundancy controller, receiving the sequence number or the next sequence number and providing the sequence number or the next sequence number to a secondary replication function. The method further comprises, at the secondary replication function, receiving the sequence number or the next sequence number and configuring a sequence generation function with the next sequence number.

Systems and methods are disclosed herein that enable Time Sensitive Networking (TSN) network or Deterministic Networking (DetNet) network replication function fallback. In some embodiments, a method comprises, at a primary replication function, obtaining a packet in a particular stream, obtaining a sequence number for the packet, generating M copies of the packet each comprising the sequence number, transmitting the M copies, and providing, to a redundancy controller, the sequence number or a next sequence number of a next packet to be transmitted for the particular stream. The method further comprises, at the redundancy controller, receiving the sequence number or the next sequence number and providing the sequence number or the next sequence number to a secondary replication function. The method further comprises, at the secondary replication function, receiving the sequence number or the next sequence number and configuring a sequence generation function with the next sequence number.

This application provides a model training-based communication method and apparatus, and a system, to effectively decrease a data amount of a parameter transmitted between the communication device and the central server. The method includes: The communication device determines a change amount of a first model parameter value. If the communication device determines, based on the change amount of the first model parameter value, that a first model parameter is stable, the communication device stops sending an update amount of the first model parameter value to the central server in a preset time period. The update amount of the first model parameter value is determined by the communication device based on user data in a process of performing model training. The communication device receives a second model parameter value sent by the central server.

This application provides a model training-based communication method and apparatus, and a system, to effectively decrease a data amount of a parameter transmitted between the communication device and the central server. The method includes: The communication device determines a change amount of a first model parameter value. If the communication device determines, based on the change amount of the first model parameter value, that a first model parameter is stable, the communication device stops sending an update amount of the first model parameter value to the central server in a preset time period. The update amount of the first model parameter value is determined by the communication device based on user data in a process of performing model training. The communication device receives a second model parameter value sent by the central server.

A reception unit (210) receives an addition requesting frame for requesting addition of a new flow. A first search unit (241) performs, using a network-information database (280), a first search for searching for a schedule and a path assignable to the new flow without the schedule and the path of each existing flow being changed, when the addition requesting frame is received. A second search unit (242) performs a second search for changing the schedule and the path of each existing flow and searching for the schedule and the path assignable to the new flow, using the network-information database, when the schedule and the path assignable to the new flow have not been found by the first search. A response unit (260) transmits an addition responding frame.