Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. The system includes an upper-level energy-management module, at least one lower-level energy-management module coupled to the upper-level energy-management module, and at least one component coupled to the lower-level energy-management module. The component is configured to provide a performance model associated with the component to the lower-level energy-management module. The lower-level energy-management module is configured to provide an aggregated model to the upper-level energy-management module.

Abstract: One embodiment of the present invention provides managing component driver for an energy-management system that manages energy within a predominantly closed power system. The component driver includes a receiving mechanism configured to receive current status information for a component associated with the component driver, a model-construction mechanism configured to construct a performance model for the component, and a transmitting mechanism configured to transmit the performance model to an optimization and control module.

Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. The system includes an identifying mechanism configured to identify a number of components coupled to the energy-management system, a receiving mechanism configured to receive current status information of the components, an evaluating mechanism configured to evaluate future energy need, a planning mechanism configured to plan future energy activities based on the energy need and the current status information, and a controlling mechanism configured to control operations of the components based on the planned energy activities.

Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. During operation, the system obtains one or more control actions that control energy transitions of a plurality of components, receives transitional characteristics associated with the components, and schedules the energy transitions by generating a set of offsets. A respective offset results in a delay of at least one energy transition.

Abstract: One embodiment of the present invention provides a system for resolving energy imbalance within an electrical grid. During operation, the system receives an imbalance signal and current outputs from a regulation service subsystem and a demand response subsystem. Subsequently, the system generates control signals for controlling future outputs of the regulation service subsystem and the demand response subsystem based on the imbalance signal and the current outputs, and applies the generated control signals to the regulation service subsystem and the demand response subsystem.

Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. The system includes an identifying mechanism configured to identify a number of components coupled to the energy-management system, a receiving mechanism configured to receive current status information of the components, an evaluating mechanism configured to evaluate future energy need, a planning mechanism configured to plan future energy activities based on the energy need and the current status information, and a controlling mechanism configured to control operations of the components based on the planned energy activities.

Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. The system includes an upper-level energy-management module, at least one lower-level energy-management module coupled to the upper-level energy-management module, and at least one component coupled to the lower-level energy-management module. The component is configured to provide a performance model associated with the component to the lower-level energy-management module. The lower-level energy-management module is configured to provide an aggregated model to the upper-level energy-management module.

Abstract: One embodiment of the present invention provides managing component driver for an energy-management system that manages energy within a predominantly closed power system. The component driver includes a receiving mechanism configured to receive current status information for a component associated with the component driver, a model-construction mechanism configured to construct a performance model for the component, and a transmitting mechanism configured to transmit the performance model to an optimization and control module.

Abstract: One embodiment of the present invention provides an energy-management system for managing energy within a predominantly closed power system. During operation, the system obtains one or more control actions that control energy transitions of a plurality of components, receives transitional characteristics associated with the components, and schedules the energy transitions by generating a set of offsets. A respective offset results in a delay of at least one energy transition.

Abstract: One embodiment of the present invention provides a system for resolving energy imbalance within an electrical grid. During operation, the system receives an imbalance signal and current outputs from a regulation service subsystem and a demand response subsystem. Subsequently, the system generates control signals for controlling future outputs of the regulation service subsystem and the demand response subsystem based on the imbalance signal and the current outputs, and applies the generated control signals to the regulation service subsystem and the demand response subsystem.