A toilet seat lighting apparatus 10 is provided so that and individual can enter a bathroom at night to use the toilet 12 which provides light and allows the user to determine if the toilet seat 20 is up or down without turning on the bathroom light. The apparatus is provided with a motion sensor circuit 30 which detects motion when an individual enters the bathroom and a pressure sensor circuit 40 which is activated by the motion sensor circuit. Once the pressure sensor circuit 40 is activated it will activate switch 72 which in turn will illuminate a red light 26 to indicate the toilet seat 20 is down or a green light 28 to indicate the seat 20 is up.

Disclosed are methods and apparatus for a lighting unit (600) that may adaptably achieve a plurality of lighting effects. A plurality of LEDs (641) producing a light output having at least one adaptable light output characteristic may be provided and controlled by a controller (650) electrically coupled to the plurality of LEDs (641). The controller may control the at least one adaptable light output characteristic in accordance with received lighting configuration data (651) that is specific to a particular lighting implementation (606).

A quantum dot composition according to an embodiment of the disclosure includes a quantum dot, a first compound including a first functional group, and a solvent, and the first functional group includes at least one among an acetal group and a ketal group.

A light-emitting element includes a light-emitting section and a driving circuit that drives the light-emitting section. The driving circuit includes at least (A) a drive transistor that is a p-channel field effect transistor, (B) an image-signal writing transistor that is a p-channel field effect transistor, (C) a light-emission control transistor that is a p-channel field effect transistor, and (D) a capacitor. Each of the drive transistor, image-signal writing transistor, and light-emission control transistor is provided in an n-type well formed in a p-type silicon semiconductor substrate. A first source/drain region of the drive transistor is electrically connected to the n-type well in which the drive transistor is formed.

An illumination device, system and method are provided herein for emulating sunlight along a daytime or nighttime locus. Sunlight is emulated depending on the path length of the sun relative to a structure containing the illumination device and system. One or more illumination devices can be grouped together and perform the sunlight emulation along the locus by producing different color temperatures throughout the day by all illumination devices within that group producing the same color temperature changes throughout the day. Moreover, a particular advantage of the preferred embodiments is the ability to manually change at any time the emulated natural sunlight output from the one or more groups of illumination devices and advantageously change the color output more so at certain times than at other times by simply actuating a trigger on a dimmer associated with a virtual or physical keypad.

Apparatuses and systems are provided for changing the spectrum of light emission from a light-emitting diode (LED) light set. The LED light set may include LEDs, each of which having at least a first LED chip and a second LED chip configured to emit light at differing wavelengths. The first and second LED chips may be connected in series with opposite polarities. Responsive to receiving a power flow in a first direction from a power terminal, the first LED chip may emit light of a first color while the second LED chip may remain powered off. Responsive to receiving the power flow in a second direction opposite the first direction from the power source, the second LED chip may emit light of a second color different than the first color while the first LED chip may remain powered off.

A solid state lighting panel sequentially energizes a plurality of LED lighting banks at the zero crossing points of the sinusoidal input line voltage. Each LED lighting bank is provided with a soft start circuit to ramp up the luminous intensity gradually. The energizing of one LED lighting bank at a time at zero cross, in combination with soft start ramp, keeps inrush spikes below the ultimate steady state operating current level. The lighting panel is further provided with line-in and line-out surge protection, along with a specific arrangement of terminals within a terminal block, the provision of surge protectors therein, the use of optically isolated solid state relays, and a plurality of well-placed circuit breakers to provide enhanced surge tolerance.

In one aspect, a device includes a processor, a communication interface accessible to the processor, and storage accessible to the processor. The storage bears instructions executable by the processor to identify an activity associated with a user. The instructions are also executable by the processor to use the communication interface to transmit at least one command to a light output apparatus to adjust light from the light output apparatus based on the identified activity.

In one embodiment, a Light Emitting Diode (LED) driving device for driving a plurality of LEDs has a switching matrix utilizing a plurality of one of a turn off thyristors or turn off triacs coupled to the plurality of LEDs. A controller is coupled to the switching matrix responsive to a voltage of a rectified AC halfwave, wherein combinations of the plurality of LEDs are altered to ensure a maximum operating voltage of the plurality of LEDs is not exceeded. A current limiting device is coupled to the combinations of the plurality of LED to regulate current.

In a second embodiment an offline charge pump utilizes a switching matrix to recombine capacitors in accordance with the voltage on the AC half wave and then in accordance with a desired output voltage to feed a load, such that said recombinations occur at a frequency much higher than the frequency of the AC rectified half wave such that charge is “pumped” from the input at one voltage to the output at another voltage through the AC halfwave while providing a constant output voltage to the load.

In one example, a method includes generating, by a current source of a device, a first portion of a power signal that drives one or more load elements. In this example, a second portion of the power signal is generated by one or more components that are external to the device and are in parallel to the current source such that the second portion of the power signal does not flow through the current source.