A wireless lighting control system is provided to create a lighting pattern by remotely controlling a plurality of lighting devices according to groups, thereby improving a lighting effect. The wireless lighting control system includes a first lighting device electrically connected with a first smart device to act as a master, and a plurality of second lighting devices electrically connected with a plurality of second smart devices to act as slaves, respectively. If a group for lighting control and control pattern information according to groups are selected from the first smart device, the first lighting device transmits the control pattern information according to the groups to the second lighting devices through a wireless communication scheme. At least one of lighting units of the second lighting devices and display units of the second smart devices is controlled based on the control pattern information according to the groups.

Brief Summary: The claim in simple terms is the simple ultraviolet illuminating device and its location underneath the specialized liquid in the bottle making the complete invention, however not obvious because it has not here before been an item of commerce. Again, not limited to the example described but for illustrative purposes the invention in its principle shall be described. Since the device will work with the intrinsic property of the chemical in the specialized liquid, those skilled in the art will appreciate the chemical quinine dissolved in water as an example, will fluoresce with UV light. The claim is not for the specialized liquid, but for the device, which is held under the vessel, which requires the aforementioned specialized liquid to be held in the vessel. Clearly the device itself will illuminate what shines in its path, but the device's purpose is to illuminate the matter as described.

This invention is intended to illuminate the vessel from below for cosmetic or aesthetic purposes. Ideally the machine is built to fit self contained within the void in the bottom of the vessel for practical purposes but can be adapted with a base collar to contain the apparatus and attach to the vessel. This novel, unprecedented invention consists of several components working in concert to create a specific illumined event with a specialized liquid contained in a flask. Those skilled in the arts will recognize a flashlight, LED, battery, and glass or vessel to hold any liquid have all been precedented. This invention covers the placement of said specialized liquid in said glass or vessel as described in the attached diagrams to illicit the illumination broadly described in this application. Moreover, not limited to the example described, is the claim of a specialized liquid subjected to UV radiation to cause that specialized liquid to fluoresce inside its container via the second part of said invention placed underneath the vessel. Each component is dependent upon the other. The claim is for a device described in detail and shown in FIGS. 1 and 2 comprising: component one which is a diffusion layer, component two which is an ultraviolet filter, component three which is a light emitting diode (LED) or LED array, component four a solid support, component five a battery, component six a battery holder, component seven a spacer, component eight a reflective material, component nine an adhesive and component ten an on/off switch, held under the glass or container, or vessel which will cause a special and specific illumination or fluorescing. The specialized liquid as described is, for example, a potable drink such as an alcoholic beverage.

A method for activating and/or deactivating the phosphorescence of a structure is disclosed. The structure may include a first and a second material, wherein a phosphor is admixed with the first material and oxygen is present in the region of the phosphor. The second material may be oxygen-impermeable at an ambient temperature and, in the oxygen-impermeable state, act as an oxygen barrier between the first material and a surrounding environment. To activate the phosphorescence, in a first activation step, oxygen present in the structure is photochemically deactivated by irradiating the structure with light of a first characteristic, and, in a second activation step, the phosphorescence is activated by irradiating the structure with light of a second characteristic. To deactivate the phosphorescence, oxygen is introduced into the structure by heating the structure and/or by irradiating the structure with light of a third characteristic.

A method for activating and/or deactivating the phosphorescence of a structure is disclosed. The structure may include a first and a second material, wherein a phosphor is admixed with the first material and oxygen is present in the region of the phosphor. The second material may be oxygen-impermeable at an ambient temperature and, in the oxygen-impermeable state, act as an oxygen barrier between the first material and a surrounding environment. To activate the phosphorescence, in a first activation step, oxygen present in the structure is photochemically deactivated by irradiating the structure with light of a first characteristic, and, in a second activation step, the phosphorescence is activated by irradiating the structure with light of a second characteristic. To deactivate the phosphorescence, oxygen is introduced into the structure by heating the structure and/or by irradiating the structure with light of a third characteristic.

The jewelry member according to the present disclosure includes: a plurality of spherical bodies that are three-dimensionally arranged regularly and include an amorphous silicic acid; and a resin that is located in a gap among adjacent spherical bodies of the plurality of spherical bodies and includes a fluorescent dye.

The jewelry member according to the present disclosure includes: a plurality of spherical bodies that are three-dimensionally arranged regularly and include an amorphous silicic acid; and a resin that is located in a gap among adjacent spherical bodies of the plurality of spherical bodies and includes a fluorescent dye.

Photoluminous markers can include a photoluminescent outer surface and an inner surface configured to affix to a surface of a building element, and an overlay having an outer surface and an inner surface, the inner surface being removably coupled to a surface area of the photoluminescent outer surface of the photoluminous marker, wherein the overlay permits light emitted from the photoluminescent outer surface to be visible.

Photoluminous markers can include a photoluminescent outer surface and an inner surface configured to affix to a surface of a building element, and an overlay having an outer surface and an inner surface, the inner surface being removably coupled to a surface area of the photoluminescent outer surface of the photoluminous marker, wherein the overlay permits light emitted from the photoluminescent outer surface to be visible.

A light-emitting apparatus includes a base, a first semiconductor radiation emitting diode, having a top surface and a side wall, disposed on the base, a transparent structure disposed on the base and surrounding the side wall and covering the top surface, and a phosphor structure placed within the transparent structure surrounding the side wall and covering the top surface. The first semiconductor radiation emitting diode has a width smaller than that of the base and is configured to emit a light which can be converted into a forward transferred down-converted radiation light and a back transferred down-converted radiation light by the phosphor structure. At least a portion of the forward transferred down-converted radiation light and the back transferred down-converted radiation light are emitted toward the base.

A light-emitting apparatus includes a base, a first semiconductor radiation emitting diode, having a top surface and a side wall, disposed on the base, a transparent structure disposed on the base and surrounding the side wall and covering the top surface, and a phosphor structure placed within the transparent structure surrounding the side wall and covering the top surface. The first semiconductor radiation emitting diode has a width smaller than that of the base and is configured to emit a light which can be converted into a forward transferred down-converted radiation light and a back transferred down-converted radiation light by the phosphor structure. At least a portion of the forward transferred down-converted radiation light and the back transferred down-converted radiation light are emitted toward the base.