A lighting fault diagnosis method includes determining a fault item among a plurality of fault items based on fault symptom data of a test for each fault item, and recommending a repair method suitable for the determined fault item.

The present invention relates to a driver module for use in a light fixture, especially an outdoor light fixture. The driver module is arranged for wirelessly powering a further module and for transmitting data from and/or to this further module. The further module can be a sensor module or a communications module. This allows for easy replacement of modules in light fixtures, late stage configuration of light fixtures and for upgradeability of light fixtures.

A system and a method for automatically creating and operating a functional association of multiple luminaires is proposed. The system consists of two or more devices that each contain one or more sensors, logic processing circuitry and communication circuitry that is able to transmit messages between devices. The set of devices that constitute the members of a functional association is selected from a larger set of candidate devices. The selection process involves each device comparing the sensor data received from neighboring devices relating to occupancy and daylight sensors against the device's occupancy and daylight sensor data.

A luminaire includes: at least one digital sensor; an illumination element; a main power supply including driver functions configured to provide power to the illumination element; and an integrated digital lighting controller in communication with the main power supply and the at least one digital sensor. The integrated digital lighting controller configured to: receive digital signals corresponding to a sensed parameter from the at least one digital sensor; determine a lighting characteristic for the illumination element based at least in part on the digital signals from the at least one digital sensor; and generate one or more control signals to the main power supply to control the driver functions to provide power to the illumination element to produce the determined lighting characteristic.

An adaptive inductive ballast is provided with the capability to communicate with a remote device powered by the ballast. To improve the operation of the ballast, the ballast changes its operating characteristics based upon information received from the remote device. Further, the ballast may provide a path for the remote device to communicate with device other than the adaptive inductive ballast.

Disclosed are an apparatus and method for testing a luminaire based on USB. The apparatus for testing a luminaire based on USB includes a power measurement unit for measuring power consumption by measuring power input from a host system to a luminaire based on USB; a message interpretation unit for generating a result of interpretation of a message based on a USB-based control message sent and received between the host system and the luminaire; an illuminance reception unit for receiving a result of measurement of illuminance of the luminaire, measured by a light reception device; and an information generation unit for generating test result information based on a result of the measurement of the power consumption, the result of the interpretation of the message, and the result of the measurement of the illuminance.

A lighting circuit for a light source includes a drive circuit that supplies a lamp current to the light source, detects the lamp current, and executes feedback control such that the lamp current approaches a target current, and an overcurrent protection circuit that is inserted between the drive circuit and the light source and that restricts the lamp current flowing into the light source so that the lamp current does not exceed an overcurrent threshold value. The overcurrent protection circuit includes a transistor, an inductor, a rectifier, a current sensor that generates a current detection signal according to the lamp current, and an overcurrent protection controller that controls ON/OFF of the transistor based on the current detection signal and the overcurrent threshold value. The transistor, the inductor and the rectifier are disposed in a T-shape.

Aspects are described for a test configuration for emergency lighting fixtures. In one example, a light fixture includes a lighting element, a battery, a clock, and a processor. The processor is configurable via a user interface. The processor is configured to test the light fixture. The testing includes illuminating the lighting element for a predetermined duration using the battery as a power source. The testing is initiated by a timer that uses the clock. The processor of the light fixture receives input, via the user interface, adjusting a value for the start timer. Based on the start timer expiring, the processor initiates a test of the light fixture for the predetermined duration. The processor further indicates a result of the test via the user interface. Based on the test being successful, the processor resets the start timer.

A street lamp controller comprises a switch configured to turn on and turn off a street lamp, a control module adapted to control the turning on and turning off of the switch, a detection module adapted to detect a data element relevant to operation of the street lamp, a data acquisition module connected to the detection module and adapted to acquire the data element detected by the detection module, and a wireless transmission module. The wireless transmission module communicates with a server and is adapted to transmit the data element acquired by the data acquisition module to the server and receive a control instruction sent from the server. The control module is adapted to communicate with the server via the wireless transmission module and is adapted to control the street lamp based on the control instruction received by the wireless transmission module.

A system of monitoring and/or maintaining remotely located autonomously powered lights, security systems, parking meters, and the like is operable to receive data signals from a number of the devices, and provide a comparison with other similar devices in the same geographic region to detect a default condition of a particular device, and/or assess whether the defect is environmental or particular to the specific device itself. The system includes memory for storing operating parameters and data, and outputs modified control commands to the devices in response to sensed performance, past performance and/or self-learning algorithms. The system operates to provide for the monitoring and/or control of individual device operating parameters on an individual or regional basis, over preset periods.