In a discharge lamp driving device, a mixed period is provided, in which a first period in which an alternating current is supplied and a second period in which a direct current is supplied are alternately repeated and a third period alternately including a first direct current period and a second direct current period in which a direct current having a polarity opposite to a polarity of the direct current in the first direct current period is supplied. Length of the second direct current period is smaller than 0.5 ms. A total of lengths of the first direct current periods in the third period is larger than length of the second period. The third period is not provided at least when the inter-electrode voltage is smaller than a first predetermined value or when a cumulative lighting time of the discharge lamp is smaller than a second predetermined value.

There is provided an illumination apparatus including an illumination unit, a reception unit, and a control unit configured to control illumination of the illumination unit in accordance with a default illumination pattern. When the reception unit receives an illumination pattern, the control unit performs illumination control different from the illumination according to the default illumination pattern.

A discharge lamp driving device includes a discharge lamp driving section configured to supply a driving current to a discharge lamp, a control section configured to control the discharge lamp driving section, and a voltage detecting section configured to detect an inter-electrode voltage. The control section supplies a driving current including a first alternating current when the inter-electrode voltage is equal to or higher than a first voltage, supplies a driving current including a second alternating current having a frequency which is lower than a frequency of the first alternating current when the inter-electrode voltage is lower than the first voltage and equal to or higher than a second voltage lower than the first voltage, and supplies a driving current including a third alternating current having a frequency which is higher than the frequency of the first alternating current when the inter-electrode voltage is lower than the second voltage.

A discharge lamp driving device includes a discharge lamp driving section configured to supply a driving current to a discharge lamp, a control section configured to control the discharge lamp driving section, and a voltage detecting section configured to detect an inter-electrode voltage. The control section supplies a driving current including a first alternating current when the inter-electrode voltage is equal to or higher than a first voltage, supplies a driving current including a second alternating current having a frequency which is lower than a frequency of the first alternating current when the inter-electrode voltage is lower than the first voltage and equal to or higher than a second voltage lower than the first voltage, and supplies a driving current including a third alternating current having a frequency which is higher than the frequency of the first alternating current when the inter-electrode voltage is lower than the second voltage.

Systems, methods, and computer program products for remote configuration of one or more power supplies, particularly lighting power supplies, are disclosed. A configuration signal that includes a setting for a parameter is generated and then transmitted to a power supply. The power supply decodes the configuration signal and, if one or more certain conditions are met, configures the power supply according to information provided in the configuration signal.

A method includes activating a transistor providing current to a load via an inductor based on values stored at a first timer and at a second timer. The second timer is enabled based a value of a current conducted at the inductor and based on a value of a reference current. The transistor is deactivated in response to determining that a measurement of time elapsed at the first timer is a predetermined multiple of the second measurement of time.

A wireless detection and control device is provided, which is applicable a lighting device, and may include a first connection interface, a processing module, a detection module and a control module. The first connection interface may be detachably coupled to the power conversion module of the lighting device. The processing module may be coupled to the first connection interface. The detection module may include two second connection interfaces, and be detachably coupled to the processing module via one of the second connection interfaces; the detection module may detect the change of the surrounding environment to generate a detection signal. The control module may be detachably coupled to the processing module. The detection module may transmit the detection signal to the power conversion module, or transmit the detection signal to the control module for the control module to generate a control signal accordingly so as to control a controlled device.

A wireless detection and control device is provided, which is applicable a lighting device, and may include a first connection interface, a processing module, a detection module and a control module. The first connection interface may be detachably coupled to the power conversion module of the lighting device. The processing module may be coupled to the first connection interface. The detection module may include two second connection interfaces, and be detachably coupled to the processing module via one of the second connection interfaces; the detection module may detect the change of the surrounding environment to generate a detection signal. The control module may be detachably coupled to the processing module. The detection module may transmit the detection signal to the power conversion module, or transmit the detection signal to the control module for the control module to generate a control signal accordingly so as to control a controlled device.

A system and method for controlling power transfer between a power grid and at least one load. In at least one embodiment, the system includes a controller having a power regulator. The controller obtains grid data related to the power grid. The power regulator of the controller enables or disables and/or increases or decreases the power transfer between the power grid and a first load based at least in part on the obtained grid data and data relating to a power requirement of the first load. The power regulator may be coupled in line between an electric panel connected to the power grid and the first load. The controller may be coupled to the first load through a wiring system of a building. Multiple controllers may be coupled respectively to multiple loads, wherein each controller is configured to control a power transfer between the power grid and a respective load.

An illumination device and method is provided herein for controlling individual light emitting diodes (LEDs) in an LED illumination device, so that a desired luminous flux and a desired chromaticity of the device can be maintained over time as the LEDs age. According to one embodiment, the method comprises applying drive currents to a plurality of LED chains substantially continuously to produce illumination, measuring a photocurrent induced on the photodetector in response to the illumination produced by each LED chain, one LED chain at a time, and received by the photodetector, and measuring a forward voltage developed across the photodetector by applying a non-operative drive current to the photodetector. For each LED chain, the method may further comprise determining an expected photocurrent value corresponding to the forward voltage measured across the photodetector and the drive current currently applied to the LED chain by applying one or more interpolation techniques to a table of stored calibration values correlating forward voltage and photocurrent to drive current at a plurality of different temperatures, and adjusting the drive current currently applied to the LED chain if a difference exists between the expected photocurrent value and the measured photocurrent.