Systems, devices, and methods are disclosed for an agent device within a company's network firewall to initiate an HTTP connection with a cloud-based gateway and then upgrade the connection to a WebSockets protocol in order to have an interactive session. Over this interactive session, a mobile device, which connects to the cloud-based intermediary, can request data from servers inside the company's firewalls. Because the firewall is traversed using HTTP protocols (with WebSockets), it can be as safe as letting employees browse the web from inside the company's network.

In one embodiment, a method includes processing network data models at a network device operating in a network comprising a plurality of network components, each of the network components associated with one of the network data models, performing semantic matching at the network device for at least two of the network data models, the semantic matching comprising computing labels for elements of the network data models utilizing label computation algorithms configured for notational conventions used in the network data models, computing contexts for the elements based on a hierarchy of each of the network data models, removing one or more of the labels used to form the contexts to create reduced contexts, and computing a semantic relationship for the reduced contexts of the network data models. The network data models are mapped at the network device based on the semantic matching for use in a network application. An apparatus and logic are also disclosed herein.

This application provides a network configuration method, apparatus, and system. The method includes: determining, based on a mapping relationship, that a first data node in a first YANG data model corresponds to a second data node in a second YANG data model, where the first data node and the second data node include a same indication operation, and the mapping relationship includes a correspondence between a data node in the first YANG data model and a data node in the second YANG data model; and generating a first packet based on the second data node.

Network elements are managed with a server to support client data models from heterogeneous data sources. A server receives a first query for configuration data of a network element to be returned in a first model. The server determines a model type for the configuration data of the network element. When the model type is a second model that is not the first model, the server sends a second query to the network element for the configuration data to be returned in the second model and transforms the configuration data received from the network element into the first model. Additionally, the server returns the configuration data in the first model as a response to the first query.

A device-communication system may receive, from a user device via a first network, communication data originating from a first device connected to the user device via a second network having a type different from that of the first network. The device-communication system may process the communication data to determine a corresponding device-management system, and may communicate further with the user device for additional identification information, if necessary. The device-communication system determines which of a plurality of device-management systems should receive the communication data and sends the data to the appropriate system.

Techniques described herein register an endpoint device, such as a utility meter, with multiple headend systems. A system described herein includes a utility meter, which measures consumption of a resource, and a Network Management System (NMS) headend system, which manages a network. The utility meter joins the network and obtains an Internet Protocol (IP) address of the NMS headend system. The utility meter transmits a network registration request to the NMS headend system using the IP address of the NMS headend system and receives, from the NMS headend system, network-related settings of the network. The utility meter obtains an IP address of a second headend system configured to provide a service over the network. Further, the utility meter receives, from the second headend system, configuration settings for using the service of the second headend system and, as such, configures the radio with the network-related settings and the configuration settings.

Techniques are described with regard to application integration management. An associated computer-implemented method includes receiving from at least one user a request to map a plurality of data fields associated with a workflow during an application integration session and automatically mapping all data fields among the plurality of data fields for which a mapping confidence value is greater than or equal to a confidence level threshold set at a default value. The method further includes receiving mapping evaluations from each of the at least one user for each automatic data field mapping based upon the confidence level threshold set at the default value, processing at least one confidence level threshold adjustment input selection from one or more of the at least one user, and deriving at least one candidate default confidence level threshold value based upon the at least one confidence level threshold adjustment input selection.

Techniques are described with regard to application integration management. An associated computer-implemented method includes receiving from at least one user a request to map a plurality of data fields associated with a workflow during an application integration session and automatically mapping all data fields among the plurality of data fields for which a mapping confidence value is greater than or equal to a confidence level threshold set at a default value. The method further includes receiving mapping evaluations from each of the at least one user for each automatic data field mapping based upon the confidence level threshold set at the default value, processing at least one confidence level threshold adjustment input selection from one or more of the at least one user, and deriving at least one candidate default confidence level threshold value based upon the at least one confidence level threshold adjustment input selection.

Introspection into containers running in virtual machines (VMs) that are instantiated on a host computer is achieved. A method of processing an introspection command for a container, funning in a virtual machine, is carried out by a VM management process, and includes the steps of receiving a first request that is formulated according to a first protocol, e.g., transmission control protocol, and includes the introspection command, identifying the virtual machine from the first request, formulating a second request that includes the introspection command, according to a second protocol (e.g., virtual socket protocol), and transmitting the second request to a container management process running in the virtual machine for the container management process to execute the introspection command.

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.