Protocol agnostic wrapping (PAW) and/or data analytics engine (DAE) functions are embedded within a service capability exposure function (SCEF) entity for handling dynamic device triggering, event monitoring, and/or reporting of Internet of things (IoT) devices. The enhanced SCEF creates a dynamic mobility network infrastructure model for global IoT connectivity and new services delivery. The PAW function can be utilized for enhancing massive IoT devices connectivity with their respective application servers in the next-generation mobility network. By employing the PAW function, the SCEF can generate and securely expose flexible application programming interfaces (APIs) to the external network of various third party IoT application service providers, which in turn can utilize the APIs to access their targeted IoT devices via network elements and extract critical device and network capabilities on an event basis.

It is provided a method, comprising monitoring if a generic objective for a network is received; translating the generic objective into specific objectives based on a behavioral matrix if the generic objective is received, wherein each of the specific objectives is specific for a respective network element; requesting, for each of the specific objectives, an automation function of the respective network element to achieve the specific objective, identifying, for each of the specific objectives, based on a stored association table, a distributed control function controlling the automation function of the respective network element; informing, for each of the specific objectives, the identified distributed control function on the specific objective for the respective network element; supervising if a feedback is received from one of the distributed control functions, wherein the feedback indicates to which degree one of the specific objectives is achieved; adapting the behavioral matrix based on the feedback.

The present invention includes embodiments of systems and methods for addressing the interdependencies that result from integrating the computing resources of multiple hardware and software providers. The integrated, multi-provider cloud-based platform of the present invention employs abstraction layers for communicating with and integrating the resources of multiple back-end hardware providers, multiple software providers and multiple license servers. These abstraction layers and associated functionality free users not only from having to implement and configure provider-specific protocols, but also from having to address interdependencies among selected hardware, software and license servers on a job-level basis or at other levels of granularity.

The present invention includes embodiments of systems and methods for addressing the interdependencies that result from integrating the computing resources of multiple hardware and software providers. The integrated, multi-provider cloud-based platform of the present invention employs abstraction layers for communicating with and integrating the resources of multiple back-end hardware providers, multiple software providers and multiple license servers. These abstraction layers and associated functionality free users not only from having to implement and configure provider-specific protocols, but also from having to address interdependencies among selected hardware, software and license servers on a job-level basis or at other levels of granularity.

Novel tools and techniques are provided for implementing network management layer configuration management. In some embodiments, a system might determine one or more network devices in a network for implementing a service arising from a service request that originates from a client device over the network. The system might further determine network technology utilized by each of the one or more network devices, and might generate flow domain information (in some cases, in the form of a flow domain network (“FDN”) object), using flow domain analysis, based at least in part on the determined network devices and/or the determined network technology. The system might automatically configure at least one of the network devices to enable performance of the service (which might include, without limitation, service activation, service modification, fault isolation, and/or performance monitoring), based at least in part on the generated flow domain information.

A method and system for managing a large number of servers and their server components distributed throughout a heterogeneous computing environment is provided. In one embodiment, an authenticated user, such as a IT system administrator, can securely and simultaneously control and configure multiple servers, supporting different operating systems, through a “virtual server.” A virtual server is an abstract model representing a collection of actual target servers. To represent multiple physical servers as one virtual server, abstract system calls that extend execution of operating-system-specific system calls to multiple servers, regardless of their supported operating systems, are used. A virtual server is implemented by a virtual server client and a collection of virtual server agents associated with a collection of actual servers.

Instantiating a resource of an IT-service includes analyzing a service model of the IT-service where the service model includes a node representing a resource for providing the IT-service. A resource type of the resource being indicated by the node is determined, and a service provider catalog is evaluated to determine a resource manager operable to instantiate the resource and an address of the resource manager. A request is sent to the address of the resource manager for a description of a resource-manager-specific API of the resource manager. Upon receipt of the requested description, at least one abstract method for instantiating the resource is overridden with a resource-manager specific method of the resource-manager-specific API, and the resource-manager specific method for instantiating the resource represented by the node is executed.

There is provided improved management of a communications network including a plurality of sub-systems for providing services to subscribers. Data is received from a plurality of source systems in a communications network, said source systems encoding data according to different data models. Rules of processing the data received data from each of the source systems are defined. At least one customer experience event of the communications network is generated on the basis of the rules.

Methods, systems, and computer-readable media for selecting and managing a public cloud-computing network to host a client's account information are provided. Initially, the client issues a request to a coordination engine, which understands rules language of various public clouds, to update the account information residing on a target cloud. The target cloud was previously selected from the various public clouds as a function of desirable criteria specified by the client in light of properties (e.g., pricing, security, and reliability) dynamically abstracted from the public clouds. When addressing the request, the coordination engine extracts command(s) from the request and automatically translates the command(s) consistent with the rules language of the target cloud. Upon delivery to the target cloud, the translated command(s) affect reading of or writing to the account information. Accordingly, the client is absolved from converting instructions into a format that is expected by the target cloud.

Various embodiments provide methods, devices, and non-transitory processor-readable storage media enabling network probing with a communication device based on the communication device sending a probe via a first network connection and receiving the probe via a second network connection. By leveraging a capability of a communication device to establish two network connections at the same time, various embodiments may enable a single communication device to act as both a probing client and a probing server. In this manner, various embodiments may enable standalone network probing, i.e., network probing that may not require a remote dedicated probing server to act as a probe generator or a probe sink.