Systems and methods are provided for automatically controlling a physical device. A tracking system monitors the locations of multiple physical objects, and their respective locations are updated in a virtual environment. Within the virtual environment, a first virtual object, corresponding to a first physical object, is paired with a dynamic zone that remains constant in shape and moves with the first virtual object. When a second virtual object, corresponding to a second physical object, enters the dynamic zone, then the physical device is triggered to act. For example, the physical device is a media projector or light that shines onto the current position of the dynamic zone, or the physical device is a robotic camera that points to the dynamic zone.

The present invention refers to an intelligent switch device for controlling lighting devices within an electrical installation, so as to control the switching on, off, and intensity of illumination by means of a mobile or web application and a user interface, in a local or remote manner; and a central control system that allows the intelligent switch devices to be configured and controlled by radio communication.

A lighting device utilizes physical or virtual separation of elements within the lighting device to isolate a first portion of data for delivery to a first data network from a second portion of data for delivery to a second data network. The first portion of data relates to a first signal generated responsive to a first sensed condition. The second portion of data may relate to the first signal or to a second signal generated responsive to the first sensed condition or a second sensed condition. The lighting device utilizes a first communication interface to deliver the first portion of data to the first data network and a second communication interface to deliver the second portion of data to the second data network.

A low-voltage controller (LVC) is configured to utilize a low-voltage signal to operate a high-voltage load, such as, for example, a lamp. The LVC is configured to receive a low-voltage step signal at a switch input. The LVC has a line input for connection to a source of power at a line voltage and a load output for connection to a first load, and a dimmer for setting an intensity of the first load. Subsequent step signals may alter the intensity of the load. A method for low-voltage control of a load is provided. A method includes the steps of receiving a first switch signal at a switch input of an LVC; setting a lamp to a first intensity; receiving a second switch signal at the switch input; and setting the lamp to a second intensity.

Disclosed are various techniques for lighting control of groups of light fixtures by a remote device. The remote device receives, via a wireless network interface, an identifier from a photocontrol device that manages light output of the light fixture. The remote device transmits a request to establish a point-to-point communication session directly with the photocontrol device using the wireless network interface. Upon establishing the communication session, the remote device receives a list of photocontrols discovered by the photocontrol device via the photocontrol network. In response to input received, via a user interface of the remote device, to adjust a dimming schedule for a group of the photocontrols, the remote device instructs the photocontrol device to transmit, via the photocontrol network, an adjustment to a configuration for the group.

A lighting audit system includes a lighting audit docking station in communication with the smart device and a database, where the lighting audit docking station includes a targeting unit and a camera. A lighting audit method includes providing a physical parameter to a lighting audit table for a space-under-study, representing the space-under-study on a virtual map presented on a display, adding surface characteristic data for the space-under-study into the lighting audit table, measuring the physical dimensions of the space-under-study using the targeting unit, the physical dimension measurements being stored in the lighting audit table, entering into the lighting audit table parameters for a luminaire located in the space-under-study, and calculating a lighting audit for the space-under-study based on data in the lighting audit table.

This disclosure relates to systems and methods for controlling electrical loads in one or more areas. The system includes a room controller having a microprocessor for accessing data and providing commands, memory for storing information operably connected to the microprocessor, a relay for powering a load based on commands from the microprocessor, and a port for connecting a peripheral device. The system also includes a peripheral device connected to the port and configured to send data to the controller indicating the type of peripheral device; and a load connected to the relay.

The present disclosure relates to determining one or more of a space occupancy score, space energy score, and space efficiency score for a collection of lighting endpoints in a lighting network. The space occupancy score is indicative of how effective the occupancy groups are configured for a given space or the utilization level for a space. The space energy score is indicative of how much energy the collection of lighting endpoints use or will likely use based on their configurations, actual use, or a combination thereof. The space efficiency score is indicative of the overall efficiency associated with the collection of lighting endpoints based on both occupancy and energy related metrics.

This disclosure describes systems, methods, and apparatus for wireless and non-line-of-sight commissioning of smart devices. Smart devices can broadcast a first radio message that is detected by an ID tool during commissioning. The first radio messages can be unique to each device, such that the ID tool can send a second radio message addressed to a select device, the address based on the first radio message from the select/addressed device. The addressed device can respond to confirm the identity and location of the addressed device. The ID tool can then send a third radio message with a registration request command, again addressed to the selected installed device. In response, the selected installed device can enter a registration request mode and transmit an identification to a commissioning system, whereby that device's identity is now know to the system and can be wirelessly controlled.

An illumination system and method is provided for readily mapping a plurality of scenes along a dimcurve form a natural show for one or more groups of LED illumination devices. Mapping can be performed using a graphical user interface on a remote controller wirelessly linked to the illumination devices. A keypad is preferably configured for button control of changes to color temperature as a function of brightness along each of the various dimcurves for each of the various groups of illumination devices controlled by a corresponding keypad to allow momentary or persistent override and reprogram of the natural show. Modification to a scene further comprises modifications to scenes before and after the currently modified scene to provide a smoothing dimcurve modification. Global keypad can be used to control multiple zones arranged throughout a structure to switch between a natural show that emulates outdoor sunlight conditions to a panic show when an intruder is detected.