A light fixture includes a light source, a wavelength-conversion material, and a reflector. The light source is configured to emit a first radiation, and has a front surface and a back surface. The wavelength-conversion material is arranged under the front surface and configured to convert the first radiation to a second radiation which has a first portion not able to reach the reflector and a second portion able to reach the reflector. The reflector is arranged over the back surface and configured to reflect the second portion away from the light source without passing through the wavelength-conversion material. The reflector has an end distant from the light source and is arranged in an elevation different from that of the wavelength-conversion material.

[Problem] To provide an illumination system with which a visual effect is provided such that it is possible to give an appearance of expanding depth on the far side of a wall face, even if a person stands directly in front thereof. [Solution] An illumination system (100) comprises a light source (130), and a reflection board (120) that provides a reflection face that reflects illumination light from the light source (130). The reflection lace of the reflection board (120) is a processed reflection face in which are disposed a plurality of grooves which are very narrow parallel straight lines or parallel curved lines with respect to a flat plane. A support body (110) supports the light source (130) facing and in close proximity to the processed reflection board of the reflection board (120). Light points appear, arranged perpendicularly in the center of the reflection board (120) facing the light source. The formation locations of virtual images of each of the light points are formed further in the depth direction from the processed reflection board the further apart they are vertically, and thus a viewer has the sense of viewing a light beam track which is formed when a horizontal plane, which seemingly expands horizontally in the depth of the wall face, is illuminated, and has the sense of viewing an expanding space in the depth direction of the wall face.

[Problem] To provide an illumination system with which a visual effect is provided such that it is possible to give an appearance of expanding depth on the far side of a wall face, even if a person stands directly in front thereof. [Solution] An illumination system (100) comprises a light source (130), and a reflection board (120) that provides a reflection face that reflects illumination light from the light source (130). The reflection lace of the reflection board (120) is a processed reflection face in which are disposed a plurality of grooves which are very narrow parallel straight lines or parallel curved lines with respect to a flat plane. A support body (110) supports the light source (130) facing and in close proximity to the processed reflection board of the reflection board (120). Light points appear, arranged perpendicularly in the center of the reflection board (120) facing the light source. The formation locations of virtual images of each of the light points are formed further in the depth direction from the processed reflection board the further apart they are vertically, and thus a viewer has the sense of viewing a light beam track which is formed when a horizontal plane, which seemingly expands horizontally in the depth of the wall face, is illuminated, and has the sense of viewing an expanding space in the depth direction of the wall face.

Devices used for workspace illumination include, for example, a panel and a solid-state based optical system arranged inside an enclosure of the panel. The panel can be a cubicle divider. In one aspect, an illumination device includes a mount; a panel including a first face and a second opposing face. The panel is vertically supported by the mount along a horizontal dimension of the first and second faces. Further, the panel forms an enclosure between the first and the second face. Additionally, the illumination device includes a first luminaire module arranged in the enclosure and configured to output light in a first output angular range. The light output in the first output angular range has a prevalent propagation direction with a vertical component towards a first target area.

A light fixture includes a fixture body having a mount, a mounting stem, and a receiver. The mount is configured to mount onto a ceiling surface and suspend the fixture body. The mounting stem has a first end connected to the mount and a second end. The receiver is disposed on the second end of the mounting stem below the first end with respect to the ceiling surface. The light fixture includes a socket disposed on the receiver for receiving a light emitter and a frame having a first end connected to the fixture body and extending downward and away from the fixture body with respect to the ceiling surface to a second end located below the received light emitter. A power receptacle and/or a communication receptacle is/are disposed on the frame in a location below the fixture body and the received light emitter with respect to the ceiling surface.

The present invention provides methods and systems for setting up light scenes. These methods and system automate the control of variable parameters after defining a set of fixtures and static properties of the fixtures in a given environment and a selected mood.

A lighting system includes a first light device having a housing; a suction means secured to a first end of the housing, the suction means being configured to removably secure the housing to a transparent structure; a light carried within the housing; and a power source conductively coupled to the light. The method includes securing the housing to the transparent structure; and directing light through the transparent structure with the light.

A deck light assembly for attachment to a deck railing includes a C-shaped body with a core nesting within a cover and a top plate extending between two legs. The body includes a top plate extending between a first leg and a second leg. An LED light and a battery may each be disposed within the body between the core and the cover. Each of the legs of the core may define a clamping member, with the clamping members in mirror-image pairs across from one-another for securing the deck light assembly upon the deck railing, and each clamping member having a V-shaped cross-section with a top portion extending downwardly and inwardly away from the associated leg to a knuckle, and with a bottom portion extending downwardly from the knuckle and outwardly toward the associated leg. The clamping members may be flexible outwardly for allowing the deck light assembly to be easily removed or repositioned on the deck railing.

A reconfigurable modular cornice box display system includes a cornice box having a front member, a left member and a right member which collectively form an outwardly facing display surface. One or more decor pieces can be selectively positioned and magnetically affixed anywhere on the display surface. The decor pieces are magnetically affixed to discrete elements arrayed in the cornice box. A decor piece illumination system includes a tri-color back light source and a magnetic sensor associated with each of said discrete elements operative to sense the magnetic coupling of a given decor piece to a given discrete element and to back illuminate said given décor piece. An electronic control system selectively activates the décor piece illumination system in response to operator inputs and microprocessor based programming instructions. A flood light assembly is disposed within said cornice box which is longitudinally and rotationally repositionable. The light sources are tri-color devices.

A projector apparatus that may include a first plurality of adjacent translucent lenses on at least one side of an inner lens, said inner lens configured to rotate and translate about an axis (A) of the inner lens; a second plurality of adjacent translucent lenses formed on at least one side of a concave outer lens; a light source configured to direct a portion of light through the rotatable and translatable inner lens and then through the concave outer lens; and a motor configured to rotatably and translatably drive the inner lens in an oscillating manner about and along the axis of the concave inner lens (A); so that the oscillating inner lens imparts a moving textured image for modification through the fixed concave outer lens for display upon a surface, such as a ceiling to simulate a moving liquid surface.