A nightlight including a base and an electrical prong secured to the base and adapted to be inserted into an electrical outlet is disclosed. A main circuit is coupled to the electrical prong and contained within the base. A flexible neon LED strip is coupled to the main circuit for receiving an electrical current. A support frame is configured in the shape of an image wherein the support frame has an arcuate shaped cross-section or a C-shaped cross-section sized to receive the flexible neon LED strip. The flexible neon LED strip is positioned along the support frame whereby the flexible neon LED strip when energized emits light corresponding to the image and illuminates an area adjacent the night light. A sound transducer may produce an electrical signal as a function of an ambient sound. The flexible neon LED strip may comprise an RGB LED, an RGB IC, or a solid color LED to produce different colors of light. The main circuit may vary the color of the emitted light that is produced by the flexible neon LED strip as a function of a switch, a remote control, or the ambient sound. The support frame may comprise a back wall and a plurality of side walls where the back wall is translucent or transparent and where the flexible neon LED strip may emit light out of a front surface and a back surface of the flexible neon LED strip. Alternatively, the support frame may comprise an arcuate cross-section where the back wall is translucent or transparent and where the flexible neon LED strip is cylindrical and may emit light out of a front surface and a back surface or all surfaces of the flexible neon LED strip.

A wall-mounted cabinet includes a cabinet body and a cabinet door coupled to the cabinet body. The cabinet door includes a door frame, a first layer disposed on a first side of the door frame, a second layer disposed on a second side of the door frame opposite of the first side, a light assembly coupled to the second layer and configured to illuminate through the second layer, and a magnifying mirror removably coupled to an area of the second layer that is surrounded by the light assembly.

A lighting module includes: a substrate; a light source located on the substrate; a first lens on which light emitted from the light source is to be incident; and a first holder to which the substrate and the first lens are fixed. Light exiting the first lens is substantially parallel light that is substantially parallel to the optical axis when viewed from a first direction intersecting an optical axis of the light source. The light exiting the first lens is substantially parallel light oblique to the optical axis when viewed from a second direction intersecting the optical axis and the first direction. A first end part of the first lens in the second direction is fixed to the first holder. When viewed from a third direction in which the optical axis extends, the first holder does not protrude outward of the first lens in the second direction.

An LED filament and a lamp are disclosed. The LED filament includes a substrate, a conductive circuit, a control chip, light-emitting chips, and electrical connection terminals. The conductive circuit includes an independent signal control circuit. The control chip is a bare-die chip, and has a VDD interface, a GND interface, an IN interface, an OUT interface, and LED control output ports. Two ends of the substrate have four electrical connection terminals electrically connected to the VDD interface, the GND interface, the IN interface and the OUT interface, respectively. Both ends of the first light-emitting chips are electrically connected to the LED control output ports and the VDD interface to form a light-emitting circuit. All components are integrated and packaged, small in size and easy to shape, so as to reduce production costs and diversify the shapes of lamps.

Most conventional LED lighting devices emit light in a fixed direction and beam angle. When changes in illumination area are needed, users often must move the fixture or install additional lighting units, which leads to inconvenience and reduced efficiency. Traditional devices rely on secondary optics or fixed housing to adjust beam shape, but they lack real-time dynamic control. There is therefore a demand for a lighting structure that can rapidly switch between spotlight and floodlight modes to improve usability and lighting flexibility.

Pet paw boots with movement activated lighting device is disclosed that helps pet owners maintain visibility of their pet in dimly lit or inclement weather conditions are disclosed. The dog paw boots with movement activated lighting devices comprise a base component or portion with an illumination component or portion. Further, a body component or portion is comprised of an adjustable strap to secure the device to the canine. The device can illuminate when motion is detected, or pressure is placed down on the device. Additionally, canines become visible to other pedestrians and drivers, preventing accidents in poor conditions. Further, tracking technology can be added to the device to ensure the location of the canine. The device also includes a battery pack to power the illumination components.

A system for use with a billiards table may include addressable multi-color LED strips, a controller and a user device. The controller may be configured to send signals through the LED strips to control which one or more pixels are activated and one or more colors of light to be produced by corresponding one or more LEDs for the one or more activated pixels. The user device may communicate with the controller and may implement a program configured to enable a user of the user device to send lighting commands to the controller during gameplay. The lighting commands may indicate user-desired changes to lighting provided by the addressable multi-color LED strips. The controller may send corresponding signals to the addressable multi-color LED light strips to implement the changes to the lighting.

A lighting system and luminaire replicates attributes of natural sunlight and the sky. An array of light emitters capable of emitting light closely mimicking natural sunlight. This emitted light features an adjustable correlated color temperature (CCT) that spans from 1900 K to 6500 K, faithfully reproducing the Sun's appearance across different times of the day. To ensure precision in spectral matching, the system operates within a defined wavelength range of 400 nm to 1400 nm. At least one light emitter with a wavelength within the range of 760 nm to 1400 nm is incorporated to guarantee accurate representation. A luminaire equipped with a panel interacts with the multitude of light emitters, proficiently emitting color-tunable light and simulating diverse sky scenes. To facilitate control and customization, a dedicated control system is seamlessly integrated into the luminaire, enabling precise adjustment of the correlated color temperature and spectral power distribution.

A nightlight including a base and an electrical prong secured to the base and adapted to be inserted into an electrical outlet is disclosed. A main circuit is coupled to the electrical prong and contained within the base. A flexible neon LED strip is coupled to the main circuit for receiving an electrical current. A support frame is configured in the shape of an image wherein the support frame has an arcuate shaped cross-section or a C-shaped cross-section sized to receive the flexible neon LED strip. The flexible neon LED strip is positioned along the support frame whereby the flexible neon LED strip when energized emits light corresponding to the image and illuminates an area adjacent the night light. A sound transducer may produce an electrical signal as a function of an ambient sound. The flexible neon LED strip may comprise an RGB LED, an RGB IC, or a solid color LED to produce different colors of light. The main circuit may vary the color of the emitted light that is produced by the flexible neon LED strip as a function of a switch, a remote control, or the ambient sound. The support frame may comprise a back wall and a plurality of side walls where the back wall is translucent or transparent and where the flexible neon LED strip may emit light out of a front surface and a back surface of the flexible neon LED strip. Alternatively, the support frame may comprise an arcuate cross-section where the back wall is translucent or transparent and where the flexible neon LED strip is cylindrical and may emit light out of a front surface and a back surface or all surfaces of the flexible neon LED strip.

An illuminator includes: a plurality of light sources; and an exterior cover that covers at least a part of a light emission space by the plurality of light sources. The exterior cover includes a first light radiation wall and a second light radiation wall that allow light emitted from the plurality of light sources to pass therethrough to radiate the light to the outside. The first light radiation wall and the second light radiation wall are colorless transparent or milky flat plates and are continuous with each other with a linear ridge therebetween. At least one light source of the plurality of light sources emits light of variable colors.