The invention provides a lighting panel, for use for example within a modular surface system, comprising one or more strips of solid state lighting elements associated with a reflector structure. The lighting panel is adapted for improved uniformity of light intensity across the width of its output area. Lighting elements comprise two or more subsets, each subset adapted to collectively generate a different light intensity profile across the width of the panel output window. The subsets are selectively adapted to generate profiles which, when blended, mutually offset one another's deviations from some common mean intensity across the width of the output window, thereby generating a combined intensity profile of improved uniformity. Embodiments include arrangements in which subsets of lighting elements are adapted to have differing actual or virtual optical path lengths to the reflector surface. Also provided are embodiments further comprising an acoustically absorbing back surface, for providing an acoustic dampening function.

The disclosure relates to a lamp in the technical field of illuminating, which includes more than two groups of illuminating devices, a plurality of groups of rotary connecting members, and a base mounting member. The more than two groups of illuminating devices are connected by the rotary connecting members, and each of the rotary connecting members includes a first rotating part and a second rotating part. The first rotating part is rotatably matched with the second rotating part, and the first rotating part and the second rotating part are detachably mounted on two adjacent groups of illuminating devices, and the more than two groups of illuminating devices are also mounted on the base mounting member, which has an advantage of an enlarged illuminating area, thus breaking through bottleneck of a smaller illuminating area of a single safety lamp.

A light fixture is disclosed. The light fixture includes: a mounting base, with a surface for interfacing with a wall; a fixture face plate; a decorative fixture element with a light socket; and a catch mechanism for securing the fixture face plate to the mounting base. The catch mechanism includes; at least one catch receiver, at least one catch aperture, and at least one catch insert. The mounting base is secured to a wall. The fixture face plate is secured to the mounting base when the at least one catch insert is inserted into the catch aperture and then rotated into the at least one catch receiver.

A display device includes a first wall, a second wall disposed opposed to the first wall, a third wall disposed in a direction crossing the first wall and the second wall and provided with a mounting portion, a substrate disposed between the first wall and the second wall and provided with a light emitting portion, and a display portion to permit transmission of light irradiated from the light emitting portion and mounted on the mounting portion. As viewed in a direction perpendicular to a normal direction of the substrate and parallel to the first and second walls, a distance between the first wall and the second wall is shorter than a length of the substrate, and the substrate is inclined with respect to the first and second walls.

A luminaire includes a door frame assembly that comprises an end plate. The end plate includes a top edge and a bottom edge that is opposite to the top edge, where the end plate extends from the bottom edge to the top edge. Further, the end plate includes a notch. Furthermore, the end plate may include a light redirecting flange that may be coupled to or integral with the end plate. The light redirecting flange may be positioned adjacent the notch in the end plate and at an angle with the end plate to redirect light from a light source of the luminaire that exits through the notch back towards a lens of the luminaire.

A light emitting arrangement (100, 200, 300) is provided, comprising: a body (10) of solid material having a surface (11); a light guiding member (101, 110) partially embedded into said body, having a plurality of discrete light outcoupling regions (103) comprising light outcoupling means (230, 730, 830, 930) distributed along a longitudinal direction of the light guiding member, and a plurality of discrete, non-outcoupling regions (102) distributed along a longitudinal direction of the light guiding member, wherein said plurality of light non-outcoupling regions of the light guiding member are embedded by said body and said plurality of light outcoupling regions of the light guiding member are exposed on the surface of said body, wherein said non-outcoupling regions (102) form light incoupling regions comprising light incoupling means (220, 320, 420, 520, 620); and a plurality of solid state light sources (12) embedded within said body (10) of solid material arranged to emit light towards said light incoupling regions. The light emitting arrangement provides a body with an illuminated surface, and the plurality of light outcoupling regions enables efficient lighting, with no or little loss of light.

An illumination device configured to emit illumination light has a light source arranged inside a housing generating the illumination light; a diffusing panel attached to the housing; and a projector arranged inside a space formed by the housing and a part of the diffusing panel for projecting an image onto a projection surface. An optical unit is arranged so that an incident direction of a light flux incident from a display element provided in the projector onto a projection optical system of the projector is substantially vertical or in a direction closer to a vertical direction than a direction parallel to a horizontal plane, or so that an optical axis of the projection optical system on which the light flux from the display element provided in the projector is incident is substantially vertical or in a direction closer to the vertical direction than the direction parallel to the horizontal plane.

A luminaire includes a radio wave sensor and a luminaire body. The luminaire body includes a first plate to be attached to a building surface and a second plate facing each other forming an internal space. The luminaire body holds the radio wave sensor between the first plate and the second plate. The radio wave sensor includes an antenna for transmitting and receiving the radio waves. The luminaire body includes an opening and a limiter. The opening is formed in the second plate to allow radio waves transmitted from the antenna to exit to an outside of the luminaire body. The limiter is provided between the antenna and the opening to limit a radiation area of the radio waves transmitted from the antenna.

A lighting system is disclosed that includes elongated LED light fixture with one or more master circuit boards configured to power light emitting diodes. The elongated LED light fixtures include modular light boards with arrays of light emitting diodes that interchangeably couple to the matched connectors on the master circuit board. The system further includes elongated LED light fixtures with telescoping end features, fenestrated diffuser optics at ends of the elongated LED fight fixtures and/or pivoting corner features that join sections of the elongated LED light fixtures.

A lighting element for an illuminated hardscape. The lighting element includes a body structure defining a dispersion surface. A light fixture is positioned within the body structure and is configured to provide a light which is dispersed through the body structure to the dispersion surface. The body structure is formed from a clear or translucent material. An illuminated hardscaping is also provided.