A supply and demand control device includes: a first communication unit which communicates, via a communication network, with an electrical device which belongs to a customer and consumes power from a power system; and a control unit which obtains a frequency of the power system, and start observation control if the obtained frequency falls below a lower limit of a predetermined frequency range, in which in the observation control, the control unit determines start time for reducing power consumption by the electrical device via the first communication unit, based on a rate of change in frequency obtained after the observation control is started, and starts reducing the power consumption at the start time if the obtained frequency does not return to within the predetermined frequency range within an observation duration which is a duration from start of the observation control to the start time.

An energy management capsule is disclosed, being a mains-powered device with multiple sensors or electrical output controllers connected to the Internet. Web services analyse sensor data for controlling electrical outputs and providing information about significant changes to predicted sensor values. Several Energy Management Capsules may be interconnected via mains powerlines, wireless communications or wired digital networks. It reports failure of mains power supply.

A power management method comprises a step A of transmitting a first message from a power management server to a local control apparatus according to a first protocol. The power management server manages a facility connected to a power grid. The local control apparatus is provided in the facility. A communication between the local control apparatus and an equipment provided in the facility is performed according to a second protocol different from the first protocol. The step A includes a step of transmitting the first message in a manner capable of identifying a control for the local control apparatus and a control for a target equipment which is the equipment designated by the power management server.

An electrical management system for managing a smart home. A plurality of end units such as electrical outlets and electrical switches sample the electricity going through the end-unit at least 1,000 times per second. The information is communicated to a server, which analyzes the data across many installations and can alert the user for any abnormal electrical situation in the home.

A power management system comprises a plurality of HEMSs 10 and a CEMS 40. The CEMS 40 transmits, to each HEMS 10, a notification request for requesting a notification of an amount of power that can be reduced from power currently consumed by a load connected to each HEMS 10, in response to a power curtailment signal. Each HEMS 10 transmits, to the CEMS 40, reducible power information including the amount of power that can be reduced from the power currently consumed, in response to the notification request. The CEMS 40 transmits, to each HEMS 10, power reduction information including an amount of power that should be reduced in each consumer 70, in response to the power curtailment signal and the reducible power information.

A control system for use in controlling operation of an electrical appliance, including: an electrical appliance housing having a control module; and a power source; a control knob including: an attachment element configured for releasably attaching the control knob to an outer surface of the housing; and an input/output module; a wireless power transfer system configured for wirelessly transferring power from the power source through the electrical appliance housing and to the input/output module for use in powering the input/output module; and a wireless control signaling module configured for wirelessly communicating a control signal from the control knob through the housing to the control module within the electrical appliance housing, said control signal received by the control module being indicative of an operational position/state of the control knob, and whereby said control module is configured for controlling operation of the electrical appliance by reference to the received wireless control signal.

The present invention is directed to monitoring or control of power production. A power production monitoring system may include a power production monitoring panel that is also configured to operate a premises control system. The power production monitoring system may include a gateway unit that receives signals from a power production source and sends signals to a power production monitoring panel.

A method of controlling a plurality of outlets and a first and a second non-transitory medium for use in connection with in a power distribution. The power distribution system includes a handheld device, a power distribution device, and the plurality of outlets. The handheld device includes a first controller. The power distribution device includes a second controller and is coupled to the plurality of outlets to provide electrical power thereto. The power distribution device is physically separated from the plurality of outlets and is located not in close proximity to an outlet of the plurality of outlets. Each outlet of the plurality of outlets includes a socket and indicia located proximate to the socket. The first non-transitory medium includes instructions that when executed by the first controller cause the first controller to scan indicia of a first outlet and receive a set of input data. The first non-transitory medium also includes instructions that when executed by the first controller cause the first controller to determine and transmit a target setting of the first outlet based on the first set of input data and the scanned indicia. The second non-transitory medium includes instructions that when executed by the second controller cause the second controller to receive the target setting, and provide electrical power to the first outlet based on the target setting.

An apparatus may display a home dashboard screen. The home dashboard screen may include a rooms function that when selected, causes display of a rooms screen. The rooms screen may list rooms. The rooms screen may present a back button that when selected, causes display of the home dashboard screen. When one of the rooms is selected, a room dashboard screen may be displayed. The room dashboard screen may list selectable functions, and may present a back button and a “Go To Rooms” button either of which when selected may cause display of the rooms screen. When a selectable function is selected, a control screen may be displayed. The control screen may present controls for receiving a control input, and may present a back button that when selected, causes display of the room dashboard screen, and a “Go To Rooms” button that when selected, causes display of the rooms screen.

A demand response method, a demand response system, and a recording medium are provided. The response control method includes: determining priorities of devices to be controlled to participate in a demand response; generating respective participation profiles for the devices based on the determined priorities; and changing the priorities of the devices included in the participation profiles, based on whether participation in the demand response according to the generated participation profiles succeeds. Therefore, the user easily participates in the demand response, and thus energy can be saved.