A self-power wireless switch according to an embodiment of the present invention includes a lower body, an upper body rotatably coupled, through a rotating shaft, to one side of the lower body; a switch cover rotatably coupled to one side of the lower body, or rotatably coupled to one side of an upper cover, a switch member capable of contacting the switch cover, a printed circuit board (PCB) comprising a contact unit which may contact the switch member that has been pressed by a user, and a generator positioned at the lower surface of the PCB and supplying power to the PCB. When the user presses the switch cover, the upper body rotates, and pressure is applied to a generator bar formed on the generator, and thus power is generated.

A self-power wireless switch according to an embodiment of the present invention includes a lower body, an upper body rotatably coupled, through a rotating shaft, to one side of the lower body; a switch cover rotatably coupled to one side of the lower body, or rotatably coupled to one side of an upper cover, a switch member capable of contacting the switch cover, a printed circuit board (PCB) comprising a contact unit which may contact the switch member that has been pressed by a user, and a generator positioned at the lower surface of the PCB and supplying power to the PCB. When the user presses the switch cover, the upper body rotates, and pressure is applied to a generator bar formed on the generator, and thus power is generated.

The present invention relates to a decorative lighting panel for mounting to a home exterior via mounting holes, brackets, bolts, etc. The panel has a frame that includes a groove between a front surface and rear surface of the panel. A plurality of illumination sources in the form of LED strips or chips are disposed in the groove, for providing illumination and a retractable plastic cover is designed to reveal the LEDs when pulled down. The plastic cover generally covers the LEDs when illumination is not required. The panel has wireless capabilities allowing a remote control or a handheld electronic device with an installed software application to remotely control the operations of the panel. The panel is designed to be electrically connected to other similar panels to form a series of panels for creating a long segment of illumination.

Disclosed embodiments provide a lighting controller and illumination system. A controller may include a phase-cut dimmer, a lighting receiver module, and at least two banks of lights. In embodiments, the lights may be LED (light emitting diode) lights, and the lighting receiver module is an LED driver. A first bank of lights illuminates at a first CCT and a second bank of lights illuminates at a second CCT. The controller communicates encoded information on a carrier signal that is received by the lighting receiver module. The lighting receiver module decodes the received encoded information and adjusts the intensity of the first and second bank of lights to create a combined CCT. The combined CCT may be realized by a combination of light from the first bank of lights and light from the second bank of lights. The combined CCT may be representative of a specified CCT.

Disclosed embodiments provide a lighting controller and illumination system. A controller may include a phase-cut dimmer, a lighting receiver module, and at least two banks of lights. In embodiments, the lights may be LED (light emitting diode) lights, and the lighting receiver module is an LED driver. A first bank of lights illuminates at a first CCT and a second bank of lights illuminates at a second CCT. The controller communicates encoded information on a carrier signal that is received by the lighting receiver module. The lighting receiver module decodes the received encoded information and adjusts the intensity of the first and second bank of lights to create a combined CCT. The combined CCT may be realized by a combination of light from the first bank of lights and light from the second bank of lights. The combined CCT may be representative of a specified CCT.

A switch device includes: a receiving conversion component, configured to receive a wireless signal and convert the received wireless signal into a power supply signal; a first power component, connected to the receiving conversion component, and configured to store electrical energy based on the power supply signal; a control component, connected to the first power component, and configured to enter a working state based on the electrical energy supplied by the first power component, and generate a control signal in the working state; and a first switch component, connected to the control component, and configured to change to be in an on or off state according to the control signal, wherein the first switch component is arranged on a power supply loop of a controlled device to which a second power component is configured to supply electrical energy in the on state.

A switch device includes: a receiving conversion component, configured to receive a wireless signal and convert the received wireless signal into a power supply signal; a first power component, connected to the receiving conversion component, and configured to store electrical energy based on the power supply signal; a control component, connected to the first power component, and configured to enter a working state based on the electrical energy supplied by the first power component, and generate a control signal in the working state; and a first switch component, connected to the control component, and configured to change to be in an on or off state according to the control signal, wherein the first switch component is arranged on a power supply loop of a controlled device to which a second power component is configured to supply electrical energy in the on state.

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.

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.

A phasor measurement unit (PMU) of the present disclosure measures phasor, i.e., magnitude and phase angle of voltage and current, and related data from a specific location on the electrical gird synchronized to a common time source. The time-synchronized phasor is called a synchrophasor. In a system of the present disclosure, a plurality of PMUs transmit the synchrophasors and related data to a phasor data concentrator (PDC), which aggregates and time-aligns the data for real time and post analysis. The PMU of the present disclosure further functions as a power quality meter determining at least one of symmetrical components' phasor, frequency, rate of change of frequency, high-speed digital inputs, analog fundamental power and/or displacement power factor.