A device may include a power supply module (PSM). The PSM may receive information regarding one or more programmable restrictions associated with a power supply. The PSM may receive a measurement of voltage associated with the power supply. The PSM may determine a current associated with the power supply based on the one or more programmable restrictions, the measurement of voltage, and a first amount of power associated with the power supply. The PSM may cause a load associated with the power supply to be adjusted based on determining the current without removing power for a connection between the power supply and a power source associated with the power supply. The PSM may cause the power supply to provide a second amount of power based on causing the load associated with the power supply to be adjusted.

A resource management system includes first and second opening/closing control mechanisms and a grid manager. The first and second control mechanisms each include: a controller to transmit a signal between a resource supply source and a load, a monitor to monitor a state of a resource from the source, a storage to store a policy defining the signal corresponding to the state of the resource from the source; and a path controller to generate the signal based on a monitoring result of the monitor and the policy. The grid manager includes: a third monitor to monitor the state of the resource from the first source; and a third path controller to generate at least one of the first and second signals by controlling at least one of the first path and second path controllers based on a monitoring result of the third monitor.

A controllable electrical outlet may comprise a resonant loop antenna. The resonant loop antenna may comprise a feed loop electrically coupled to a radio-frequency (RF) communication circuit and a main loop magnetically coupled to the feed loop. The controllable electrical outlet may comprise one or more electrical receptacles configured to receive a plug of a plug-in electrical load and may be configured to control power delivered to the plug-in electrical load in response to an RF signal received via the RF communication circuit. The RF performance of the controllable electrical outlet may be substantially immune to devices plugged into the receptacles (e.g., plugs, power supplies, etc.) due to the operation of the resonant loop antenna. For example, degradation of the RF performance of the controllable electrical outlet may be less when the controllable electrical outlet includes the resonant loop antenna rather than other types of antennas.

A microgrid comprising: a plurality of devices including at least: one or more primary devices, and one or more auxiliary devices, the plurality of devices being configured to form an at least partially connected mesh network for wireless communication of information between the devices, wherein at least one of the one or more auxiliary devices is controlled in dependence on communicated information relating to the operation of at least one of the one or more primary devices.

A charge/discharge control method for a charge/discharge element includes receiving a request value (Pfr) of a frequency adjustment capacity according to a system frequency (f) of an electric power system (10) based on a priority degree (?) and the request value (Pfr) being received, the priority degree indicating a degree at which charging or discharging of an own element (EV1) is prioritized over charging or discharging of another charge/discharge element (EV2, EV3, . . . ), correcting the output property to increase an upper limit value or a lower limit value of an output range as the priority degree (?) is higher, and performing charging or discharging with an output determined based on a deviation (?f) between the system frequency (f) measured at a connection end to the electric power system (10) and a reference frequency (fref) of the electric power system (10) and the output property after the correction.

A wireless control device includes a power source, one or more sensors, one or more switches, a wireless transceiver circuit, an antenna connected to the wireless transceiver circuit, and a processor communicably coupled to the power source, the one or more sensors, the one or more switches, and the wireless transceiver circuit. The processor receives a data from the one or more sensors or the one or more switches, determines a pre-defined action associated with the data that identifies one or more external devices and one or more tasks, and transmits one or more control signals via the wireless transceiver circuit and the antenna that instruct the identified external device(s) to perform the identified task(s).

A method of adjusting an energy usage of a usage area including a step of providing a gateway device for the usage area wherein the usage area comprises at least one electrically powered device and a step of determining an energy usage of the at least one electrically powered device. The method also includes a step of creating a user energy profile and a step of adjusting the energy usage of the at least one electrically powered device in the usage area based on the energy usage of the at least one electrically powered device and based on the user energy profile.

A method includes performing by a local processor corresponding to a power consumer: detecting a power system frequency that is less than a low frequency threshold, receiving a ratio of a power demand reduction goal to a total responsive load from a power grid management processor, determining a portion of all of the appliances that are managed by the power consumer to be deactivated based on the ratio responsive to detecting the power system frequency being less than the low frequency threshold, and deactivating respective ones of the portion of appliances based on the ratio.

A battery pack management device capable of reducing power consumption while transmitting and receiving data between a master BMS and a slave BMS by using a wireless communication method. The battery pack management device according to the present disclosure includes: a master BMS including an external communicator, an internal communicator, and a master controller and a slave BMS including a power supply, a state measurement sensor, a slave wireless communicator, and a slave controller.

Power outages and restorations at customer premises can be automatically detected and reported. A method includes receiving, from a network terminal, a first notification associated with a power outage; retrieving location information associated with the network terminal; sending a second notification indicating that the outage has occurred and that includes the location information associated with the network terminal; retrieving prior outage information that corresponds to a set of network terminals associated with a group of set top boxes; determining that an outage event is triggered, when a quantity of outages is greater than a threshold, where the quantity of outages is based on the outage and other outages obtained from the prior outage information; and sending a third notification based on the determination that the outage event is triggered, where the third notification includes information associated with the quantity of outages that enables a server to remedy the outage event.