Enhancements to ornamental or holiday lighting are disclosed including remote control ornamental illumination with color pallet control whereby a user can vary the color/intensity/appearance of an individual bulb or entire light string by selecting the electronic address of the bulb and selecting its attribute. Further disclosures include: motion responsive lights which respond to sensed movement, gesture controlled lights, adjustable white color/white led sets, connectable multi-function lights, controller to sequence lights to music or other input source, rotating projection led light/tree top/table top unit, and remote controlled sequencing icicle lights and ornament lighting system.

A light switch network comprises a plurality of light switch units, each comprising a gesture interface to sense a user gesture by receiving at least one gesture signal from a sensing zone, and configured to exchange one or more gesture status signals with at least one other switch unit in the network in relation to the received gesture signal; each switch being enabled, on receiving the gesture signal: in a first mode, to change a designated switch mode and/or state in response to the gesture signal; or in a second mode, to not change the designated switch mode and/or state according to one or more conditions associated with the status signals received from the other switch unit.

An occupancy-based communication network includes two or more device control assemblies wherein each of the two or more device control assemblies includes an occupancy sensor configured to detect one or more occupants. The first device control assembly of the two or more device control assemblies is configured to receive at least one of audio or video signals associated with a first occupant proximate to the first device control assembly, determine a location of a second occupant detected by at least one occupancy sensor of the two or more device control assemblies, determine a second device control assembly of the two or more device control assemblies proximate to the second occupant, and transmit to the second device control assembly, data indicative of the at least one of audio or video signals associated with the first occupant.

A system for occupancy prediction includes one or more occupancy sensors configured to detect a current occupancy state of one or more detection zones including at least one of occupied by one or more occupants or vacant of occupants. The system including one or more occupancy sensors configured to predict a future occupancy state of the one or more zones based on the current occupancy state and one or more historical occupancy states, wherein at least one occupancy sensor of the one or more occupancy sensor is communicatively coupled to an electrical load. The system including at least one occupancy sensor is configured to actuate the electrical load based on the predicted future occupancy state of the one or more zones.

A particular smart hazard detector may itself function as a guide during a process of installation of the same at an installation location. Additionally, the installation location of the particular smart hazard detector may play a central role in how various settings of the smart hazard detector are defined and adjusted over time.

A remote control device may be configured to be mounted over the toggle actuator of a light switch and to control a load control device via wireless communication. The remote control device may include a base portion and a rotating portion supported by the base portion so as to be rotatable about the base portion. The remote control device may include a control circuit and a wireless communication circuit. The control circuit may be operably coupled to the rotating portion and to the wireless communication circuit. The control circuit may be configured to translate a force applied to the rotating portion of the remote control device into a control signal and to cause the communication circuit to transmit the control signal to the load control device.

Systems, methods, apparatus (e.g., mobile computing devices), and computer-readable media are described herein for lighting control. In various embodiments, a mobile computing device may receive input indicative of a desired lighting property adjustment for a lighting effect sensed by a light sensor of the mobile computing device. The mobile computing device may identify one or more LED-based lighting units that contribute to the sensed lighting effect. The mobile computing device may then generate, for wireless transmission to the one or more contributing LED-based lighting units, an instruction configured to cause at least some of the one or more contributing LED-based lighting units to implement the desired lighting property adjustment. In various embodiments, one or more user inputs of the mobile computing device may be selectively enabled, based on a detected lighting context, to receive the input indicative of a desired lighting property adjustment.

A lighting control device includes; a sensor that detects a state of a user and a gesture made by the user; and a controller that controls a lighting characteristic of one or more lighting devices. The sensor detects a first state and a second state of a hand of the user. In response to the sensor detect the hand of the user in the first state aiming at one lighting device, among the one or more lighting devices, the controller designates the one lighting device as a control target lighting device, and in response to the sensor detecting a predetermined gesture involving the hand in the second state, the controller controls a lighting characteristic of the control target lighting device.

An example of a building automation system utilizes intelligent system elements, some of which are lighting devices having light sources, and some of which are utility building control and automation elements. Some utility building control and automation elements include a controllable mechanism for use in control of some aspect of the building other than lighting. Another intelligent system element may include either a user interface component and be configured as a building controller, or include a detector and be configured as a sensor. Each intelligent system element includes a network communication interface, processor, memory and programming to configure the intelligent system element as a lighting device, utility building control and automation element, controller or sensor. At least one of the intelligent lighting devices is configured as a building control and automation system server. Several examples, however, implement the overall control using distributed processing.

Various methods and systems for hazard detectors are presented. Such hazard detectors may include one or more hazard sensors that are configured to detect the presence of one or more types of hazards. Such hazard detectors may include a circular or a ring-shaped light comprising a plurality of lighting elements. Such a ring-shaped light may be configured to illuminate using a plurality of colors and, possibly, a plurality of animation patterns. Such hazard detectors may include a processing system configured to cause the ring-shaped light to illuminate using the plurality of colors and the plurality of animation patterns in response to a plurality of states corresponding to the battery module and the plurality of hazard sensors.