Abstract: The autonomous cloud design system may determine a design that may appropriately mix emerging technologies and operations to provide a versatile and cost-effective or efficient solution for a given cloud site.

Abstract: Systems and methods disclosed herein relate to autonomous agents. A first autonomous agent receives, from a first sensor, a first set of event data indicating events relating to a subject. The first autonomous agent provides the first set of event data to a data aggregator. The first autonomous agent receives, from the data aggregator, correlated event data including events sensed by the first autonomous agent and a second autonomous agent. The first autonomous agent applies machine learning model to the correlated event data to predict a first pattern of activity and determines, based on the first pattern of activity, that a first action is to be performed, causing the first actuator module to perform the first action.

Abstract: A system for expansive network control comprising: a development engine includes a scenario building engine configured to build an abstracted view of at least one sub-network based on a network inventory; a gamification engine communicating with a user input/output device providing at least one simulated scenario involving a simulated network threat to the user input/output device; and a machine learning engine communicating with the gamification engine, wherein the machine learning engine generates at least one strategy, the machine learning engine capturing the scenario and the user input from the user input/output device; an expansive network control operation engine includes an expansive network control engine communicating with the machine learning engine; an execution engine communicating with the expansive network control engine; a threat detection engine communicating with at least one external threat data source, the at least one external threat data source including at least one of weather, seismic,

Abstract: An open-loop control assistance (“OLCA”) system can collect data, correlate and aggregate the data, and perform multi-dimensional analytics on the correlated and aggregated data. The OLCA system can then determine plurality of viable options for a next action to be taken by an operator in an open-loop control process, and can determine a specific option as an optimal choice for the operator to select. The OLCA system can present the plurality of viable options and a rationale explaining why the operator should select the specific option. The OLCA system can capture action(s) taken by the operator, and if the action does not correspond to the recommended action, the OLCA system can capture a reason regarding why the optimal choice was not selected. The OLCA system can analyze results from the action(s). The OLCA system can then fine-tune the open-loop control process based upon the results and the cause(s) thereof.

Abstract: Methods, systems, and apparatuses, for real-time operation control, among other things. There may be adjustments to a first device in which a first network service operates. The adjustment to the device may include moving a second network service of the first device to a second device. The first network service and the second network service may be associated with virtual machines.

Abstract: A system for expansive network control comprising: a development engine includes a scenario building engine configured to build an abstracted view of at least one sub-network based on a network inventory; a gamification engine communicating with a user input/output device providing at least one simulated scenario involving a simulated network threat to the user input/output device; and a machine learning engine communicating with the gamification engine, wherein the machine learning engine generates at least one strategy, the machine learning engine capturing the scenario and the user input from the user input/output device; an expansive network control operation engine includes an expansive network control engine communicating with the machine learning engine; an execution engine communicating with the expansive network control engine; a threat detection engine communicating with at least one external threat data source, the at least one external threat data source including at least one of weather, seismic,

Abstract: An intelligent preventative maintenance architecture for maintaining a plurality of cloud components operating within a cloud computing environment is disclosed. The architecture can perform a predictive failure analysis that monitors health of at least a portion of the plurality of cloud components that hosts a mission critical application. The predictive failure analysis receives sensor data that includes environmental data associated with environmental characteristics of the cloud computing environment and cloud component data associated with operational characteristics of at least a portion of the plurality of cloud components operating within the cloud computing environment. The predictive failure analysis analyzes the sensor data to detect an abnormal pattern within the sensor data, determines a root cause of the abnormal pattern, and predicts a probability of a failure of at least one cloud component of the plurality of cloud components.

Abstract: Systems and methods provide capacity planning, management, and engineering automation in networks including virtualization.

Abstract: A method includes receiving metadata for deploying a virtual function on a cloud network. The metadata includes a recipe, policy, and template. The method includes, based on the metadata, designing a cloud plan and a transport plan for deploying the virtual function on the cloud network to meet a forecasted demand. The method includes determining a network configuration to implement the cloud plan and the network plan based on the metadata and causing the cloud network to be configured using the network configuration. The method includes instantiating the virtual function on the configured cloud network.