A light-emitting device includes a light emitter including a light-emitting portion that emits first emission light having a first peak wavelength in a range of 380 to 425 nm and a half width of 15 to 35 nm, and a coating located over the light-emitting portion of the light emitter and containing phosphors to emit second emission light having a second peak wavelength in a range of 430 to 475 nm and having a third peak wavelength in a range of 490 to 540 nm. The light-emitting device emits external emission light having a peak region including the first peak wavelength, the second peak wavelength, and the third peak wavelength 14P02303 and having a long wavelength region defined between an upper end of the range of the third peak wavelength and a wavelength of 750 nm in which a light intensity decreases continuously.

Examples of electrical lamp fixtures for illuminating terrariums and stimulating the growth and health of reptiles, amphibians, and birds, and specifically to an improved, compact light emitting diode (LED) terrarium light apparatus are described. The lighting apparatus can incorporate one or multiple extended point source LED arrays, such as composed of high brightness LEDs of multiple wavelengths, that provide spatially and spectrally controlled light. A compact, high brightness LED terrarium light apparatus for reptiles and birds, comprises an array of multiple LED chips that provides visible light, ultraviolet light, and (optionally) infrared light, with separate control of the various spectral components.

A sweeping illumination system illuminates an aquarium with organisms requiring simulated sunlight for survival. The illumination system includes a downward-facing light housing for illuminating a top surface of the aquarium. A support arm is coupled to the light housing and enables the light housing to sweep a pattern across the top surface of the aquarium. The sweep pattern can be semi-circular or semi-elliptical along a plane parallel to the top surface of the aquarium.

A performance room includes: a luminous device for stimulating dinoflagellates and generating a luminous effect; an audio equipment for providing a piece of music, wherein the music is integrated with the luminous effect of the dinoflagellates, and the sequential tonalities and rhythms of the music are related to the switching of switching elements of the luminous device; and a field which can define a performance space, wherein the luminous effect of the dinoflagellates and the music are located in the field of the performance space. In particularly, the luminous effect is exhibited by integrating the musical melody with the dinoflagellates itself acted as a performer.

An illumination system and method configured for mitigating a growth dip and as a consequence enhancing the growth of aquatic animals in a volume of water is disclosed. The illumination system comprises at least one light source (110) comprising at least one light emitting diode arranged to emit light to the volume of water and at least one light driver (120) arranged to drive the at least one light source. The illumination system also comprises a controller (140) that is adapted to provide control signals to the light driver to increase a light intensity level of the light emitted from the at least one light source from a first light intensity level (II) to a second light intensity level (12) over a time period (T) of at least one day to two weeks, preferably at least two days to two weeks.

An aquarium has wireless lighting which is configured to turn on a lighting device provided inside the aquarium and vertically move the lighting device in water by a wireless magnetic resonance method. Therefore, a light that can be maintained in a submerged state may be provided, thereby providing better aesthetic effects than existing lights of aquariums. In addition, additional devices such as a filter can be moved in water by using a magnetic field, thereby improving functional effects.

A lighting unit for illuminating a habitat is provided. The lighting unit includes a housing and a light emitter. The operating parameters of the lighting unit may be adjusted to mimic different natural conditions.

An illumination system for cultivation of aquatic animals is disclosed for cultivation of aquatic animals in a volume of water, the cultivation using a feeding system defining a feeding axis in the volume of water. The system comprises at least a first illumination surface positioned in the volume of water and arranged for illuminating the feeding axis. The system also comprises a second illumination surface positioned in the volume of water and arranged for illuminating the feeding axis. The first illumination surface and second illumination surface are different surfaces arranged to illuminate the feeding axis from substantially different directions.

A luminaire includes a receiving element for a rotationally symmetrical glass body with a receiving opening, a rotationally symmetrical glass body arranged in the receiving opening and an annular, permanently elastic element arranged between the receiving element and the glass body, wherein the receiving element is formed with a support surface which is inclined towards the glass body and the glass body is formed with a receiving surface diametrically opposite to the support surface. The permanently elastic element is positioned in the installed state between the support surface and the receiving surface in order to fix the receiving element and the glass body positively and concentrically to each other. An annular gap is provided between glass body and receiving element for introducing the annular, permanently elastic element between support surface and receiving surface. A method for fastening the glass body in the receiving element is provided.

An aquarium system includes an aquarium tank arrangement and a light source. The light source has a controllable output of colored light projecting into the aquarium tank arrangement. The light source can provide a cycle of projecting light of at least two different colors.