A load control system may include a load control device for providing power to an electrical load and a control device that may send instructions to the load control device for providing the power to the electrical load. The control device may communicate with the load control device using a link address assigned to the load control device. The load control device may provide power to the electrical load in a manner that causes the electrical load to indicate the link address assigned to the load control device. The link address may be identified by a user or a user device. The identified link address may be associated with a load control device identifier that may identify a physical location of a load control device that is assigned the link address. A user may control a load control device at a physical location by sending instructions via the link address.

In various embodiments, a smart home device is presented. The smart home device may include at least one sensor. The smart home device may include a speaker, a light, and a motion detection sensor that detects motion in an ambient environment of the smart home device. A processing system of the smart home device may be configured to select an illumination state based on a determined status. The processing system may cause the light to illuminate based on the selected illumination state. The processing system may determine a gesture has been performed in the ambient environment of the smart home device following the light being illuminated based on the selected illumination state. The processing system may output a detail of the status via the speaker corresponding to the illumination state in response to determining the gesture has been performed.

Networked intelligent lighting devices may utilize visual light communication to perform autonomous neighbor discovery, for example, as part of a map generation process. Individually, each intelligent lighting device within an installation transmits a series of packets via visual light communication for receipt by one or more of the other intelligent lighting devices. Receiving intelligent lighting devices record the number of received packets from each transmitter. Records of numbers of received packets are conveyed via a data communication network to a centralized process. The centralized process utilizes the conveyed records to determine neighbor relationships between lighting devices, for example to generate a map of devices as located within the installation.

Hazardous or dangerous conditions may be monitored. A mode may be set to a state indicative of the condition being present. It may then be determined that the hazardous or dangerous condition has eased. An indication of the hazardous or dangerous condition easing may be output in response to the determination. Such an indication may be output as synthesized speech.

Systems and Methods disclosed herein relate to providing control of smart devices via data provided from or to a doorbell, via an application programming interface (API). The data provided by the doorbell may be submission data related to the doorbell, while received data may be reception data related to one or more smart devices, a smart-device environment structure hosting the smart devices, or both. Based upon the reception data and/or the submission data, a status of the doorbell and/or of the smart devices may be modified.

Various arrangements are presented for controlling a night light feature of a hazard detector. A user interface application executed on a mobile device may output, a graphical interface that provides an option to enable a night light feature of the hazard detector. The application may transmit data indicative of the night light feature being enabled and of an associated user account to a computer server system. The computer server system may receive and store data indicative of the night light feature being enabled and of the user account. The hazard detector may receive from the computer server system data indicative of the night light feature of the hazard detector being enabled by the application. The hazard detector may enable the plurality of LEDs to provide illumination in response to the received data indicative of the night light feature of the hazard detector being enabled by the application.

A resin curing lamp includes an outer shell, an inner shell, a control module, an interactive display, at least one lighting panel, and a rechargeable battery. The outer shell has an interior surface, an exterior surface, and an aperture. The control module, the interactive display, and the lighting panels are mounted on the interior surface. The display is aligned with the aperture and electrically connects to the control module. The lighting panels have ultraviolet light-emitting diodes (LEDs) electrically connected to the control module. The inner shell has a battery compartment, a reflective inner surface, and oculi that conduct light LEDs. The battery is electrically connected to the control module. The control module regulates the power delivered to the LEDs as selected by the user, as well as the duration as selected by the user.

A space lighting system based on energy-saving target has a control device and an execution device. The execution device is one or more luminaires arranged inside the space; the control device configures the dimming parameters of the execution device according to the passenger density in the space based on the energy-saving target of the space lighting system. The space lighting system optimizes the dimming effect according to the passenger flow density under the constraint of setting conditions based on the energy-saving target so as to improve the customer experience.

A controller for an indoor grow lighting system is provided and can include a digital communication module and an analog communication module that are each configured to communicate with a plurality of light fixtures. The controller also includes a controller area network communication module that facilitates communication with a plurality of sensors. The controller is configured to conduct different testing procedures on the light fixtures.

Disclosed are a lighting control method, a control system and a storage medium. The method includes: acquiring a user behavior representing a user emotion; inputting the user behavior into an emotion prediction network for prediction to obtain a user emotion classification result, where the emotion prediction network is obtained by training through an algorithm based on an attention mechanism; and generating a control instruction according to the emotion classification result, where the control instruction is used for modulating a lighting mode of at least one lamp device. According to the disclosure, the user emotion classification result is obtained by analyzing and predicting the user behavior, the control instruction is generated according to the emotion classification result, and the control instruction is used for controlling the preset lighting mode of the lamp device.