Provided is a method and apparatus for searching for a Maintenance End Point (MEP), and a storage medium. The method includes that: a chip of the MEP parses an obtained packet; the chip of the MEP determines whether a field of the parsed packet matches a field in a combination of a port and a Virtual Local Area Network (VLAN); and in a case where the field of the parsed packet matches the field in the combination of the port and the VLAN, the chip of the MEP determines that the MEP is found successfully.

Provided is a method and apparatus for searching for a Maintenance End Point (MEP), and a storage medium. The method includes that: a chip of the MEP parses an obtained packet; the chip of the MEP determines whether a field of the parsed packet matches a field in a combination of a port and a Virtual Local Area Network (VLAN); and in a case where the field of the parsed packet matches the field in the combination of the port and the VLAN, the chip of the MEP determines that the MEP is found successfully.

Provided are a wireless network device and an information collection method for the wireless network device, which are suitable for collecting large-capacity device information. A wireless network device is a wireless network device to be connected to a master node, the wireless network device including: a storage device that stores information on the subject device; and a control unit that detects that a storage capacity in the storage device has reached a certain capacity and performs control in such a way that information stored in the storage device is transmitted to a path to the master node.

Embodiments of this application provide a network operation and maintenance method, to resolve a problem that a mainly manual network operation and maintenance method has high costs and low operation and maintenance efficiency. The method includes: A network intelligent unit obtains first network data, performs training based on the first network data to obtain a data model, and deploys the data model. The data model is a first model, a second model, or a third model. The first model is used to determine a network control instruction to be sent to an operation support system. The second model is used to determine a network control instruction to be sent to an element/network management system. The third model is used to determine a network control instruction to be sent to a network element.

A method comprises creating template limited-administration ontologies, the template limited-administration ontologies each identifying a plurality of different managers, each of the different managers having distinct and limited system access privileges. A request is received for a limited-administration server system, the request being associated with a client entity. A particular template limited-administration ontology of the template limited-administration ontologies is selected based on the request. A deployment ontology is generated based on the particular template limited-administration ontology and the request. A limited-administration server system deployment package is generated based on the deployment ontology. The limited-administration server system deployment package is provided for execution, wherein execution of the limited-administration server system deployment package creates a limited-administration server system, the limited-administration server system being capable of controlling access to one or more other systems associated with the client entity, and the limited-administration server system being limited to administration according to the different managers.

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 method, computer program product, and computing system for use in a clustered storage system are provided. Embodiments may include providing, using a management network, one or more of external access to the clustered storage system, management of intra-cluster traffic, management of hypervisor traffic, and access to infrastructure services. Embodiments may further include allowing, using a storage network, access to the clustered storage system from within the clustered storage system and one or more external hosts. Embodiments may also include providing a migration network to allow for mobility of one or more virtual machines within clustered storage system. Embodiments may further include splitting the management network into a public management network and an internal intra-cluster management network.

Correlation of component information provided by diverse detection and data collection methods is used to discover additional components and identify and record relationships between these and still other components. Each detection and data collection method can be individually useful to discover components, and to provide at least some information about one or more discovered components to identify at least one relationship between the discovered components. When the information and component discoveries of a first detection and data collection method are properly combined with those of a second detection and data collection method, there can be a synergistic effect that greatly improves the utility and efficiency of a relationship-based network management system by enabling automated discovery of additional components and identification of additional component relationships, by automatically merging diverse views of a single component into a coherent picture of that component, and by automated prediction of component state changes based on state changes in related components.

Correlation of component information provided by diverse detection and data collection methods is used to discover additional components and identify and record relationships between these and still other components. Each detection and data collection method can be individually useful to discover components, and to provide at least some information about one or more discovered components to identify at least one relationship between the discovered components. When the information and component discoveries of a first detection and data collection method are properly combined with those of a second detection and data collection method, there can be a synergistic effect that greatly improves the utility and efficiency of a relationship-based network management system by enabling automated discovery of additional components and identification of additional component relationships, by automatically merging diverse views of a single component into a coherent picture of that component, and by automated prediction of component state changes based on state changes in related components.

A portable remote support device comprises a processing unit, a network communication unit configured to communicate with a cloud service, a video capturing unit, at least one video input port and at least one output port. The processing unit is configured to communicate video signals received via the video input port to the cloud service via the network communication unit, and to emulate pointing device signals and/or keyboard signals received via the network communication unit on said at least one output port. The portable remote support device is configured to obtain unique secure tokens.