A system is provided for controlling an aquatic habitat. The system for includes a server, a bridge, and a habitat component. The server includes a database containing information associated with a habitat component. The server also includes a communication interface for transmitting operating data for the habitat component. The bridge has a first communication unit configured to communicate with the server communication interface and transmit the operating data received from the server to the habitat component. The habitat component has a second communication unit for receiving operating data from the bridge.

Various examples of methods and systems are provided for increasing productivity of one or more photosynthetic cultures via self-powered energy output systems. In one example, a system includes a waterproof casing and an energy output module enclosed within the waterproof casing. The waterproof casing is configured to be neutrally buoyant in an enclosure comprising the one or more photosynthetic cultures. In another example, a method includes placing a self-powered energy output system within an enclosure, the self-powered energy output system being neutrally buoyant within the enclosure. The method further includes causing turbulence within the enclosure, and the self-powered energy output system harvests energy to power the self-powered energy output system via the turbulence within the enclosure.

Various examples of methods and systems are provided for increasing productivity of one or more photosynthetic cultures via self-powered energy output systems. In one example, a system includes a waterproof casing and an energy output module enclosed within the waterproof casing. The waterproof casing is configured to be neutrally buoyant in an enclosure comprising the one or more photosynthetic cultures. In another example, a method includes placing a self-powered energy output system within an enclosure, the self-powered energy output system being neutrally buoyant within the enclosure. The method further includes causing turbulence within the enclosure, and the self-powered energy output system harvests energy to power the self-powered energy output system via the turbulence within the enclosure.

An integrated coral cultivation system includes a water tank unit having at least one aquaculture tank configured to contain corals, a water supply unit for supplying aquaculture water to the water tank unit, a drain unit for discharging the aquaculture water in the water supply unit and the aquaculture tank to the outside, an air supply unit for supplying air to the water tank unit, a temperature adjustment unit for adjusting the temperature of the aquaculture water in the water tank unit, a light unit for providing lighting to the water tank unit, and a power source unit for supplying power to the water supply unit, the air supply unit, the temperature adjustment unit and the light unit.

A climate controlled display cabinet includes a frame. A stationary shelf is coupled to the frame. A plurality of operable shelves is coupled to at least one of the frame and the stationary shelf. The operable shelves are moveable between open and closed positions. A heat source is in thermal communication with the stationary shelf and the plurality of operable shelves. At least one temperature sensor monitors a temperature of an area proximate the stationary shelf and the plurality of operable shelves.

A home aquaponics grow bed having a hydroponic growing bed with a removable filter component, a depression in the hydroponic growing bed, a removable lid that houses plant and/or plants, and a port and/or hole for allowing water to flow out of the invention and into the fish tank. The grow bed attaches to standard fish tank aquariums converting the fish tank aquariums into a home aquaponics gardening kit. The grow bed enables a user to grow fresh aquaponics herbs, microgreens, medicinal plants, and vegetables in their home using a freshwater aquarium.

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.

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.

The present invention discloses an enhanced design of a multi-directional Modular Aquarium LED lighting bulbs and system where the led lights are mounted on a 3 sided heatsink forming an isosceles trapezoid. Further a system is provided where each bulb, light bulb spectrum user desires to use in either specific spectrum in nanometer ranges (ie: UV, Indigo, Violet, Royal Blue, Blue, Cyan, etc) utilizing specific kelvin spectrum (ie: 2000 k, 3000 k, 6000 k, 10,000 k, etc) can be controlled by an application. The system further updates the available colors within the mobile app and website, in order to allow the user to control the intensity as well as schedule sunset/sunrise features along the day.

The present invention discloses an enhanced design of a multi-directional Modular Aquarium LED lighting bulbs and system where the led lights are mounted on a 3 sided heatsink forming an isosceles trapezoid. Further a system is provided where each bulb, light bulb spectrum user desires to use in either specific spectrum in nanometer ranges (ie: UV, Indigo, Violet, Royal Blue, Blue, Cyan, etc) utilizing specific kelvin spectrum (ie: 2000 k, 3000 k, 6000 k, 10,000 k, etc) can be controlled by an application. The system further updates the available colors within the mobile app and website, in order to allow the user to control the intensity as well as schedule sunset/sunrise features along the day.