A network interface system defines standardized network service requests and related abstracted tasks. In examples, commands needed to configure particular network elements are dependent on the network being utilized and/or the network element(s) being utilized. The network interface system may include a standardization layer, an abstraction layer, and an application programming interface for each of a variety of available networks. Upon a request for a network service, the related abstracted tasks may be translated into network-specific commands to configure network elements of disparate networks to provide the requested service.

Apparatus and methods related to on-boarding software applications on a platform used in a content delivery and/or service provider network. In one embodiment, a centralized platform such as a premises gateway is provided to act as an application portal or store for all consumer devices that connects to a service provider network. In one variant, a software architecture is provided for the gateway which includes at least one of an open-sourced OS (e.g., OpenWrt) and containerization engine (e.g., Docker) which enables a broader range of application compatibility with the gateway itself and end user devices within the premises by abstracting the services and functions above the specific hardware/firmware configurations of each of the end user devices.

A network node and method for enhancing message communication between a first network node and a second network node in a communication network is provided. The first network node receives an input message from the second network node wherein the input message contains at least one parameter. The first network node then identifies in the received input message the presence of the at least one parameter, wherein the parameter is unknown to the first network node. After identifying at least one unknown parameter, the first network node sends a request message to the second network node for obtaining meta-data associated with the identified unknown parameter. The first network node then receives a response message from the second network node containing the said obtained meta-data associated with the identified unknown parameter. After receiving the response message, the first network node updates the obtained meta-data associated with the unknown parameter.

Disclosed are a communication method and apparatus for a plurality of administrative domains, where the plurality of administrative domains include a composite network service (NS) administrative domain and a nested network service (NS) administrative domain, and the composite NS administrative domain and the nested NS administrative domain respectively include a composite network functions virtualization orchestrator (NFVO) and a nested NFVO. According to the communication method and apparatus for a plurality of administrative domains, the composite NFVO sends a subscription request message for analysis and prediction information of a nested NS instance to the nested NFVO, and performs a corresponding management operation based on received analysis and prediction information.

This disclosure describes techniques for providing a network diagnostic system with on-premise node processing and cloud node processing to optimize bandwidth usage and decrease memory footprint. The on-premise node may receive streaming telemetry from connected network devices and encode to the telemetry data into filtered data objects. The on-premise node may determine whether the state of a network device has changed to determine to push the filtered data object to a cloud node for further diagnostic analysis. The cloud node may include a gateway and a pool of proxy servers, wherein each proxy server is designated to perform diagnostic analysis on a single product type.

This disclosure describes techniques for providing a network diagnostic system with on-premise node processing and cloud node processing to optimize bandwidth usage and decrease memory footprint. The on-premise node may receive streaming telemetry from connected network devices and encode to the telemetry data into filtered data objects. The on-premise node may determine whether the state of a network device has changed to determine to push the filtered data object to a cloud node for further diagnostic analysis. The cloud node may include a gateway and a pool of proxy servers, wherein each proxy server is designated to perform diagnostic analysis on a single product type.

An intelligent trust enabler system for a 5G IoT (fifth-generation Internet of Things) environment includes: an IoT trust enabler mounted on an edge and gateway on a fifth-generation (5G) IoT infrastructure, for providing trust information based on data collected from IoT devices and performing operation and management of connected IoT resources; and an IoT trust agent for providing a legacy environment for the IoT trust enabler.

Example aspects include techniques for collection of vendor-agnostic state and configuration information from network devices. These techniques may include receiving first device information from a network device of a network, the first device information including configuration information or state information in a vendor specific format and parsing, via a template associated with the vendor specific format, the first device information to generate parsed device information. In addition, the techniques may include generating, based on a vendor-agnostic model and the parsed device information, second device information in a vendor-agnostic format, and generating a network representation including the second device information. Further, the techniques may include dynamically generating an application programming interface (API) for accessing the network representation of the second device information via an API request.

A system and a method for performing programmable analytics on network data are described. A data layer constructs flow behavior information based on information present within headers of data packets flowing across one or more network devices configured in a computer network. An inline heuristics layer performs one or more inline heuristic operations on the flow behavior information to obtain aggregate statistical information. An integrated analytics layer performs one or more analytical operations on the flow behavior information to obtain network insights. A presentation layer filters and plots information obtained from the data layer, the inline heuristics layer, and the integrated analytics layer, based on a user input.

Systems and methods are disclosed for providing visual network programming for network management automation. One exemplary method may include providing a GUI for automating network management tasks and receiving a plurality of graphical icons. Each graphical icon may be associated with one or more operations or functions. The method may also include associating the plurality of graphical icons with a device table for defining a device queue by storing information of at least one network device in the computer network and a device data table for storing information to be retrieved from the at least one network device defined in the device queue. The method may also include generating a network application based on the plurality of graphical icons and associated device table and device data table.