A load control system may comprise load control devices for controlling respective electrical loads, and a system controller operable to transmit digital messages including different commands to the load control devices in response to a selection of a preset. The different commands may include a preset command configured to identify preset data in a device database stored at the load control device and/or a multi-output command configured to define the preset data for being stored in the device database. The system controller may decide which of the commands to transmit to the load control devices in response to the selection of the preset.

A method of controlling electrical power supply through at least one electrical power supply output of an electrical supply device includes receiving switching time and/or duration data. The received switching time and/or duration data are processed with one or more of clock times and calendar dates to provide switching time and/or duration comprising at least one supply on period and at least one supply off period. Electrical power supply through the at least one electrical power supply output is controlled in accordance with the switching time and/or duration.

A power switch configured for use in a multi-way switch system is provided. The power switch includes one or more switching elements configured to selectively couple a load to a power source. The power switch includes a power metering circuit and a communications circuit. The communications circuit can be configured to provide communications between the power switch and at least one other power switch in the switch system. The power switch can include a control device configured obtain data from the power metering circuit. The data can be indicative of power consumption of the load. The control device can be further configured to determine whether the power switch is a master power switch in the multi-way switch system based on the data.

The pending disclosure describes embodiments of systems, devices and methods of controlling load operations on customer premises based on configuration. Such embodiments include storing output control configuration rules in a memory coupled to a load system controller. Further, such embodiments include receiving configuration instructions from at least one of a remote server and user interface. In addition, such embodiments include configuring the load system into one or more zones based on configuration instructions. Moreover, such embodiments include configuring each zone to be associated with one or more input devices based on configuration instructions. Also, such embodiments include configuring each of the one or more input devices based on configuration instructions. Further, such embodiments include configuring one or more output devices based on configuring the one or more zones, one or more input devices in each zone, the configuration instructions, and the output control configuration rules.

An electrical device with a power switch has at least two different electrical operational states and a circuit which detects a sequence of momentary fluctuations of power defining a First user message, corresponding to a change in state. The circuit implements that change in state in response to detection of the First message. Another circuit detects a sequence of momentary fluctuations of power, different from the sequence of the First user message, defining a Second user message and defining a fixed Reset electrical operational state. The device also implements a change from the current electrical operational state, to the fixed Reset electrical operational state. A memory circuit stores the current electrical operational state, a number corresponding to one of the countable numbers of electrical operational state, and provides retentions of its memory, including the stored current electrical operational state, during periods of power off.

A load control device for controlling the amount of power delivered to an electrical load may include a rectifier circuit configured to receive a phase-control voltage and produce a rectified voltage. A power converter may be configured to receive the rectified voltage at an input and generate a bus voltage. An input capacitor may be coupled across the input of the power converter. The input capacitor may be adapted to charge when the magnitude of the phase control voltage is approximately zero volts. The power converter may be configured to operate in a boost mode, such that the magnitude of the bus voltage is greater than a peak magnitude of the input voltage. The power converter may be configured to operate in a buck mode to charge the input capacitor from the bus voltage when the magnitude of the phase-control voltage is approximately zero volts.

An appliance unit (3) is for electrical connection in series to a control unit (1) and to a power supply via the control unit (1). The appliance unit (3) comprises an appliance module comprising at least one controllable light generating module (23) and/or at least one controllable auxiliary module (25) for performing functionality other than light generating, and a control module (27) for negotiating a power mode for the appliance unit (3) with the control unit (1). The appliance module is controlled based on the power mode. A bypass module (21) is able to pass current through the appliance unit (3), such that the bypass module (21) is configured to pass a current to enable the control unit (1) to be powered separately from any current passed by the at least one controllable light generating module (23) and the at least one controllable auxiliary module (25).

A load control system for controlling the amount of power delivered from an AC power source to a plurality of electrical load includes a plurality of independent units responsive to a broadcast controller. Each independent unit includes at least one commander and at least one energy controller for controlling at least one of the electrical loads in response to a control signal received from the commander. The independent units are configured and operate independent of each other. The broadcast controller transmits wireless signals to the energy controllers of the independent units. The energy controllers do not respond to control signals received from the commanders of other independent units, but the energy controllers of both independent units respond to the wireless signals transmitted by broadcast controller. The energy controller may operate in different operating modes in response to the wireless signals transmitted by the broadcast controller.

Examples of lighting equipment provide services to and on behalf of a biomechatronically enhanced organism and/or a biomechatronic component of the organism. Such services include charging, communications, location-related services, control, optimization, client-server functions and distributed processing functionality. The biomechatronically enhanced organism and/or biomechatronic component utilize such services provided by and/or via the lighting equipment to enable, enhance or otherwise influence operation of the organism.

A device may detect a power removal event, determine whether the power removal event is a local power removal event or a system power removal event, and perform state correction. For example, the device may receive an indication of a state change event turning on the lighting device. The indication may be received from a sensor. For example, the sensor may include a photosensing circuit (e.g., capable of detecting light emission from the lighting device) or the sensor may include a live voltage sensor (e.g., capable of detecting a change in current driven to the lighting device). The device may then determine whether the power removal event is a system power removal event or a local power removal event. If the device determines that the power removal event is a system power removal event, the device may perform state correction (e.g., setting the lighting device to its state prior to the power removal event).