A first light source illuminates a first region. A second light source is configured to provide lower luminance than that of the first light source. The second light source illuminates a second region that overlaps the first region, and that has a larger area than that of the first region. A lighting circuit drives the first light source and the second light source according to a common lighting instruction. The lighting circuit gradually turns on the first light source and the second light source with different gradual changing time periods in response to the lighting instruction.

A light-emitting device, especially for lighting and/or signaling for a motor vehicle, includes at least a first electroluminescent module and a second electroluminescent module energized in series. Each electroluminescent module includes, in parallel: a first branch having a light source having a first direct threshold voltage beyond which the light source is gated on, and a second branch having an element such that the voltage on the terminals of the element is less than the first direct threshold voltage of the light source. A third branch has a timing module able to time a predetermined period and modify, at the end of the predetermined period, an overall impedance of the second branch so that a voltage in the second branch is greater than the first direct threshold voltage of the light source. The predetermined period in the first electroluminescent module is less than that of the second electroluminescent module.

A multi-layer metal core printed circuit board (MCPCB) has mounted on it at least one or more heat-generating LEDs and one or more devices configured to provide current to the one or more LEDs. The one or more devices may include a device that carries a steep slope voltage waveform. Since there is typically a very thin dielectric between the patterned copper layer and the metal substrate, the steep slope voltage waveform may produce a current in the metal substrate due to AC coupling via parasitic capacitance. This AC-coupled current may produce electromagnetic interference (EMI). To reduce the EMI, a local shielding area may be formed between the metal substrate and the device carrying the steep slope voltage waveform. The local shielding area may be conductive and may be electrically connected, to a DC voltage node adjacent to the one or more devices.

An input voltage stabilization circuit for a rear combination lamp includes: an optical output unit including a plurality of Organic Light Emitting Diodes (OLEDs); a voltage converter; and a feedback unit. The voltage converter is configured to supply an output voltage for driving the plurality of OLEDs by converting a first voltage supplied by a vehicle battery to the output voltage, the output voltage being different from the first voltage. The feedback unit is configured to provide, as feedback to the voltage converter, information regarding a maximum voltage value for the plurality of OLEDs. The voltage converter is further configured to adjust the output voltage based on the information provided as feedback by the feedback unit regarding the maximum.

A strip of linear lighting with distributed power conversion is disclosed. The linear lighting includes a flexible PCB. The flexible PCB is divided into repeating blocks, which are arranged electrically in parallel with one another between power and ground. Each repeating block includes power conversion and conditioning circuits. A plurality of LED light engines are connected to the outputs of the power conversion and conditioning circuits, electrically in series with one another. The power conversion and conditioning circuits typically include at least a full-bridge rectifier. A pair of conductors run the length of the PCB adjacent to it and are connected to each of the repeating blocks. A flexible, transparent covering surrounds the PCB and pair of conductors.

Plants are optimally grown under artificial narrowband Photosynthetically Active Radiation (“PAR”) of multiple colors, and color palettes, applied in but partially time-overlapping cycles. As well as a long, growing season, cycle, the colored lights are cyclically applied on a short, diurnal, cycle that often roughly simulates a peak-season sunny day at the earth latitude native to the plant. Bluer lights are applied commencing before redder lights, and are likewise terminated before the redder lights. Infrared light in particular, is preferably first applied at a time corresponding to early afternoon, and is temporally extended past a time corresponding to sunset. The colored lights and light palettes preferably rise to, and fall from, different peak intensities over periods from 10 minutes to 2 hours, and relative peak intensities of even such different colors as are used at all vary up to times two (×2) in response to differing PAR requirements of different plants. Computer-controlled colored LED lights realize all.

A display case includes a transparent LCD panel for viewing display case contents therethrough.

A smart lamp device applied to a remote host includes a lamp body, an LED module, a power supply module, a detector and a lamp frame assembly. The power supply module is contained in the lamp body and electrically connected to the LED module; the detector is installed to a lid of the lamp body and electrically connected to the LED module and the power supply module; the lamp frame assembly includes a first clamp, a second clamp and a hollow rod, and the hollow rod has a middle section and two extensions extended from both ends of the middle section, and the middle section is adjustably clamped between the first clamp and the second clamp, and the two extensions are fixed to both sides of the lamp body respectively.

Disclosed is a LED DC control circuit that comprises an AC to DC circuit, a voltage division circuit, a controller and a logic circuit. The AC to DC circuit receives an AC reference voltage and generates a sine wave reference voltage and a DC reference voltage. The voltage division circuit receives the DC reference voltage and generates a threshold voltage. The controller compares the threshold voltage with the DC reference voltage to generate an inner reference voltage. The controller receives a first PWM voltage signal to accordingly sample the inner reference voltage and then output a second PWM voltage signal. The logic circuit receives the second PWM voltage signal to generate a driving voltage and a load current for driving a power switch circuit. Within each period of the sine wave reference voltage, at least one of the driving signals of the load current is a relative maximum.

A method is described for driving light emission of a light emitting device that includes first and second electrode layers, and first and second groups of light emitting diodes between the first and second electrode layers. A first electrode voltage is provided to the first and second electrode layers to conduct the first group of light emitting diodes, and then a second electrode voltage is provided to the first and second electrode layers to conduct the second group of light emitting diodes.