A method includes determining, by a controller device that manages a plurality of network devices, device characteristic information for a network device of the plurality of network devices and selecting, by the controller device, one or more sensors from a plurality of sensors based on the device characteristic information for the network device. The method further includes outputting, by the controller device, an instruction to cause the network device to generate the one or more selected sensors at the network device and receiving, by the controller device, sensor information from the one or more selected sensors generated at the network device.

A method includes determining, by a controller device that manages a plurality of network devices, device characteristic information for a network device of the plurality of network devices and selecting, by the controller device, one or more sensors from a plurality of sensors based on the device characteristic information for the network device. The method further includes outputting, by the controller device, an instruction to cause the network device to generate the one or more selected sensors at the network device and receiving, by the controller device, sensor information from the one or more selected sensors generated at the network device.

Methods/systems are provided for extending the capabilities of OPCUA to network devices that are otherwise configured and managed using NETCONF-YANG and SNMP-MIB protocols. The extension of OPCUA allows these devices to be described in network communications in the same manner as MIB or YANG. The systems/methods provide a CUC configured to request a TSN connection on the industrial network, the CUC including an OPCUA model therein. The CUC interacts with and configures an OPCUA based industrial controller connected to the industrial network, and an OPCUA based industrial device connected to the industrial network, to determine TSN parameters required for the TSN connection. The systems/methods further provide a CNC configured to provision the TSN connection on the industrial network upon request by the CUC. In some embodiments, the CNC includes an OPCUA model therein. Alternatively, the CUC may translate the TSN parameters from OPCUA parameters to YANG-MIB parameters for the CNC.

A SOAM virtualization system for a network having at least first and second maintenance entities coupled to each other comprises a network controller coupled to at least one of the first and second maintenance entities through a tunnel for virtualizing a SOAM network function on the at least one of the first and second maintenance entities to which the network controller is coupled. The network controller may be coupled to the first and second maintenance entities through first and second tunnels, respectively. The first maintenance entity may an originator device, and the second maintenance entity may be a destination device, with the network controller virtualizing the SOAM network function on both devices. The network controller may send a packet containing a tunnel header and a SOAM frame via the first tunnel to the originator device, which then sends the packet containing the SOAM frame to the destination device.

A SOAM virtualization system for a network having at least first and second maintenance entities coupled to each other comprises a network controller coupled to at least one of the first and second maintenance entities through a tunnel for virtualizing a SOAM network function on the at least one of the first and second maintenance entities to which the network controller is coupled. The network controller may be coupled to the first and second maintenance entities through first and second tunnels, respectively. The first maintenance entity may an originator device, and the second maintenance entity may be a destination device, with the network controller virtualizing the SOAM network function on both devices. The network controller may send a packet containing a tunnel header and a SOAM frame via the first tunnel to the originator device, which then sends the packet containing the SOAM frame to the destination device.

Quantum key distribution network security survivability can be provided by receiving, at a software defined networking controller operating in a control layer of a network, a recommendation from a global analytics service operating in an application layer of the network, the recommendation for replacing a failed communication link in a quantum key distribution layer of the network, the failed communication link being detected by a quantum edge computing device operating in the quantum key distribution layer. The software defined networking controller can generate a command to cause a quantum key distribution resource to perform an action to mitigate impact from the failed communication link. The command can be sent to the quantum key distribution resource and the quantum key distribution resource can perform the action to mitigate the impact from the failed communication link.

A replacement management apparatus includes a detection section which detects a first communication speed and first setting information of a physical port used for connection for each of a communication apparatus to be replaced and a communication apparatus to be connected, and detects a second communication speed of a physical port used for connection for a replacing communication apparatus, and a generation section which generates second setting information of the physical port used for connection for each of the replacing communication apparatus and the communication apparatus to be connected based on the detected first communication speed, the detected second communication speed, and the detected first setting information.

An abnormality detection device according to the present invention is a video transmission state abnormality detection device connected via a network to a plurality of video transmission devices, an IP packet transfer device on the transmission side, an IP packet transfer device on the reception side, and a plurality of video reception devices. The video transmission state abnormality detection device prepares a transmission/reception IP flow table by aggregating IP flow information for the devices, detects an abnormality in transmission on the basis of the transmission/reception IP flow table, and specifies the location of the abnormality. The abnormality detection device according to the present invention can automatically detect the amount of traffic and specify which part of a transmission path an abnormality is caused on, without the need for advance setting. Therefore, video or sound traffic can be monitored efficiently.

In various embodiments, the techniques and supporting systems implement a recursive routing mechanism in hierarchical topological addressed environments to analyze and determine the presence of packet-forwarding errors within an IP network comprising a plurality of network-connected devices. This includes receiving, at a software defined network device, an indication of a potential packet-forwarding error between a first and second device of the plurality of network-connected devices and injecting, by the software defined network device, a test packet at an ingress to the first device. The test packet includes an initial ingress interface location identifying the first device, an alternate ingress interface location identifying the software defined network device and an egress interface location identifying the second device. A determination may then be made as to whether the test packet is received at the second device, thus indicating the existence or lack of routing errors.

Embodiments of this application disclose a network slice management method and device, and relate to the field of communications technologies. The method includes: receiving, by a first management unit, a network slice management request, where the network slice management request carries instance information or indication information of a transport network manager; and sending, by the first management unit, a transmission management request to a corresponding transport network manager based on the instance information of the transport network manager, where the transmission management request is used to deploy a transmission network. The embodiments of this application provide a method for determining a transport network manager to create a corresponding transmission network.