A power apparatus includes: a storage battery; a first communicator that communicates with external communication equipment through a short-range wireless communication; a power supply circuit that supply power of the storage battery to the electrical equipment; and a control circuitry that causes, when the first communicator receives a request signal for requesting at least one of first information regarding whether or not a power supply operation to supply the power of the storage battery to the electrical equipment through the power supply circuit is normal and second information regarding whether or not an operation of the electrical equipment using power supplied from the storage battery is normal from the external communication equipment, the first communicator to transmit response information including at least one of the first information and the second information to a transmission source of the request signal and to transmit the request signal to another power storage apparatus.

Methods and systems for performing network reconfigurations for networks including one or more renewable energy devices are described herein. In one exemplary embodiment, a network reconfiguration engine is used to determine an energy level of one or more renewable energy devices within the network. The reconfiguration engine is then capable of determining an optimal path for the network reconfiguration such that a least portion of the network's load is impacted, as well as a minimal number of switching operations are needed. The optimal path also, in one embodiment, includes performing a resiliency estimation for the post-network reconfiguration topology. An updated relay setting for the post-network reconfiguration topology is determined, and a status of any other engines associated with the reconfiguration is determined, after which the network reconfiguration is performed.

A microgrid according to an exemplary aspect of the present disclosure includes, among other things, a plurality of intelligent electronic devices configured to communicate directly with one another in a first language. Each of the intelligent electronic devices includes a controller and a gateway. The gateway is configured to convert incoming messages from the first language to a second language native to the controller. The first language is different than the second language. A method is also disclosed.

A heating system includes a first plurality of heating elements disposed within an electrostatic chuck and an electrically conductive housing. The heating system further includes one or more switching devices to control temperatures output by the first plurality of heating elements. The heating system further includes a converter that is electrically coupled to the one or more switching devices and disposed within the electrically conductive housing. The electrically conductive housing and the first plurality of heating elements are to operate in a radio frequency (RF) environment. A second plurality of elements are to operate outside of the RF environment. The converter is to communicate with a controller outside of the RF environment via a non-conductive communication link. The controller is to receive a process recipe and is to control the first plurality of heating elements and the second plurality of elements substantially simultaneously based on the process recipe.

A method includes generating, based on a process recipe, a first electrical control signal by a processing device external to a particular radio frequency (RF) environment. The method further includes converting the first electrical control signal into an alternative control signal, transmitting the alternative control signal to a converter within the particular RF environment over a non-conductive communication link, and converting the alternative control signal into a second electrical control signal by the converter. The method further includes controlling a first plurality of elements via one or more switching devices using the second electrical control signal. The method further includes generating, based on the process recipe, a third signal by the processing device and controlling a second plurality of elements disposed outside of the RF environment using the third signal. The first plurality of elements and the second plurality of elements are controlled substantially simultaneously based on the process recipe.

Aspects of the subject disclosure may include, for example, a utilities management system operable to receive via a guided wave transceiver a plurality of utility status signals from a plurality of utility sensors located at a plurality of supervised sites. Utility control data is generated based on the plurality of utility status signals. At least one control signal is generated for transmission via the guided wave transceiver to at least one of the plurality of supervised sites, and the at least one control signal includes at least one utility deployment instruction based on the utility control data. Other embodiments are disclosed.

Aspects of the subject disclosure may include, for example, a transmission system having a coupling device, a bypass circuit, a memory and a processor. The coupling device can facilitate transmission or reception of electromagnetic waves that propagate along a surface of a transmission medium. The memory can store instructions, which when executed by the processor, causes the processor to perform operations including restarting a timer to prevent the bypass circuit from disabling the transmission or reception of electromagnetic waves by the coupling device. Other embodiments are disclosed.

A method and apparatus is described for providing energy system status information. A status indication device may be mounted near an entry door for determining when an individual is about to leave an area. When the status indication device determines that an individual is about to leave an area, it displays an energy status to the individual, so that the individual can decide whether to place energy-consuming devices in a conservation mode of operation.

A wireless mesh network is configured to manage a power grid. Each node within the wireless mesh network is configured to detect and classify voltage fluctuations in power supplied by an upstream transformer coupled to the power grid. When a given node detects a particular type of fluctuation (i.e., an event), the node generates a timestamped event classification that reflects the type of event and a time when the event occurred. A server configured to manage the wireless mesh network receives timestamped event classifications from each node within the wireless mesh network and then performs a time correlation with the received timestamped event classifications to determine which nodes detected similar events. When two or more nodes detected the same event at similar times, the server determines that those nodes are coupled to the same transformer.

A system for analyzing energy usage measures one or more parameters indicative of energy usage for a plurality of sub-circuits, where the sampling rate for the measuring is substantially continuous, and automatically transmits information related to at least one of the measured parameters at a rate that enables monitoring of current energy usage. The system further detects a significant change in a measured parameter, determines whether the significant change in the measured parameter is caused by a change in energy usage, and automatically transmits information related to the significant change in the measured parameter caused by the change in energy usage after detecting the significant change.