A color temperature control method in the present disclosure includes: obtaining color coordinates and illuminance of each monochromatic lamp, and obtaining, based on the illuminance and an illuminance proportion of a color temperature, initial illuminance data of the monochromatic lamp at a current color temperature; calculating a coordinate difference between target color coordinates and mixed color coordinates obtained by performing illuminance mixing on the initial illuminance data; when the coordinate difference is within a first difference range, calculating illuminance changes of R and B based on the mixed color coordinates, the target color coordinates, correction coordinates of R, and correction coordinates of B; and obtaining latest channel values of R and B based on the illuminance changes of R and B, and regulating, based on the latest channel values, the color temperature of each monochromatic lamp on which color mixing is performed.

The present disclosure relates to an emergency lighting circuit, a control method thereof and an emergency lighting system. Normal lighting is monitored by detecting whether a charging management apparatus in the emergency lighting circuit has electric energy input. When the charging management apparatus has no electric energy input, emergency lighting may be started, and power transmitted to load lighting equipment is switched to an emergency battery apparatus through a power supply switching apparatus, which is processed by a boost inverter to provide appropriate electric energy for the load lighting equipment. A power detection apparatus detects an input-terminal power signal of the boost inverter, and regulates power of the load lighting equipment based on the input-terminal power signal. Operating power of the load lighting equipment is regulated based on the input-terminal power signal of the boost inverter. An input-terminal voltage of the boost inverter is a DC low voltage and easy to detect. Moreover, in the solution, high voltage and current are not required to be isolated for power detection, which effectively reduces detection costs and is highly reliable in power detection.

The present disclosure relates to an emergency lighting circuit, a control method thereof and an emergency lighting system. Normal lighting is monitored by detecting whether a charging management apparatus in the emergency lighting circuit has electric energy input. When the charging management apparatus has no electric energy input, emergency lighting may be started, and power transmitted to load lighting equipment is switched to an emergency battery apparatus through a power supply switching apparatus, which is processed by a boost inverter to provide appropriate electric energy for the load lighting equipment. A power detection apparatus detects an input-terminal power signal of the boost inverter, and regulates power of the load lighting equipment based on the input-terminal power signal. Operating power of the load lighting equipment is regulated based on the input-terminal power signal of the boost inverter. An input-terminal voltage of the boost inverter is a DC low voltage and easy to detect. Moreover, in the solution, high voltage and current are not required to be isolated for power detection, which effectively reduces detection costs and is highly reliable in power detection.

A control attachment for an in-wall power adapter configured to control the application of power to a load is described. The control attachment comprises a first contact element of a plurality of contact elements configured to receive a power signal; a second contact element of the plurality of contact elements configured to provide the power signal to the load; a conductor electrically coupling the first contact element to the second contact element; wherein the control attachment enables the in-wall power adapter to control the application of power received at the first contact element to be applied to the load.

A light engine that produces UVA1 light, but not UVA2 or UVB radiation, that will provide a human or animal subject a beneficial application of artificial UVA1 light without the deleterious effect of the UVA2 and UVB light. Methods of providing UVA1 light to the human or animal subject over various periods of time provide positive treatments that can reduce stress, reduce anxiety, increase a pain threshold, and induce interferon production. Exposure to UVA1 wavelength light (360-400 nm) provides a positive effect on both humans and animals. This is especially true when the humans or animals do not receive UVB and UVA2 at the time that the UVA1 light is received, and the ratio of UVA1 light to (UVA1 light+visible light) is greater than 10%.

A light engine that produces UVA1 light, but not UVA2 or UVB radiation, that will provide a human or animal subject a beneficial application of artificial UVA1 light without the deleterious effect of the UVA2 and UVB light. Methods of providing UVA1 light to the human or animal subject over various periods of time provide positive treatments that can reduce stress, reduce anxiety, increase a pain threshold, and induce interferon production. Exposure to UVA1 wavelength light (360-400 nm) provides a positive effect on both humans and animals. This is especially true when the humans or animals do not receive UVB and UVA2 at the time that the UVA1 light is received, and the ratio of UVA1 light to (UVA1 light+visible light) is greater than 10%.

Systems, and methods are described herein for identifying and/or controlling influence and/or potential influence of one or more signals on one or more properties of light emitted by one or more lighting units (100). In various embodiments, one or more signals may be identified that influence, or potentially influence, a manner in which a lighting unit controller (110) controls one or more properties of light to be emitted by a lighting unit (100). In some embodiments, a user instruction may be received to alter the manner in which the one or more signals influence how the lighting unit controller (110) controls the one or more properties of light emitted by the lighting unit (100) may be received. The lighting unit controller (110) may control a manner in which light output of the lighting unit (100) is influenced by the one or more signals in accordance with the user instruction.

An LED power transmission line with load identification function is coupled to an LED power control apparatus having a plurality of power output ports and an LED load. The LED power transmission line includes a power transmission circuit, a signal transmission circuit, and a memory apparatus. The power transmission circuit transmits a power outputted from the power output port to the LED load. The signal transmission circuit is coupled to a control module of the LED power apparatus through the power output port. The memory apparatus stores an LED specification information related to an electrical specification of the LED load. The LED specification information is provided to the control module through the signal transmission circuit so that the control module limits an output current outputted from the power output port according to the LED specification information.

A buck-boost power converter is operable in a first mode (step-down) or in a second mode (step-up). The power converter has an inductor, a flying capacitor, a network of six switches and a driver adapted to drive the network of switches with a sequence of states. Depending on the mode of operation the sequence of states comprises at least one of a first state and a second state. In the first state the ground port is coupled to the second port via two paths, a first path comprising the flying capacitor and the inductor, and a second path comprising the flying capacitor while bypassing the inductor. In the second state the first port is coupled to the second port via a path that includes the inductor and the ground port is coupled to the first port via a path that includes the flying capacitor while bypassing the inductor.

A buck-boost power converter is operable in a first mode (step-down) or in a second mode (step-up). The power converter has an inductor, a flying capacitor, a network of six switches and a driver adapted to drive the network of switches with a sequence of states. Depending on the mode of operation the sequence of states comprises at least one of a first state and a second state. In the first state the ground port is coupled to the second port via two paths, a first path comprising the flying capacitor and the inductor, and a second path comprising the flying capacitor while bypassing the inductor. In the second state the first port is coupled to the second port via a path that includes the inductor and the ground port is coupled to the first port via a path that includes the flying capacitor while bypassing the inductor.