An example aquatic imaging system comprises a light source, a first platform coupled with a image capture device and a second platform that is parallel to the platform, the image capture device having a first field of view, and, the second platform being coupled to a organism tank, first organism tank having an inner wall, outer wall and a base that defines a well capable of retaining water, the base being parallel to the second platform, the organism tank configured to receive a light beam originating from the light source and configured to project at least a portion of the light beam through the well and in a directional plane that is parallel to the base, the image capture device configured to direct the first field of view from the first platform through the well in the organism tank.

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.

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.

Methods, systems, and apparatus, including computer programs encoded on computer-storage media, for a lighting controller for sea lice detection. In some implementations, fish are contained within an elliptical tank filled with water. An imaging station located on the elliptical tank is used to capture an image of a fish from which image analysis can be performed to detect sea lice or other skin features, including lesions, on the fish. Pairs of imaging assemblies coordinate pulsing light of at least a first and a second color and capturing images of the fish while the fish is illuminated by at least the first and the second color. By using the captured images with different color light, computers can detect features on the body of a fish including sea lice, skin lesions, shortened operculum or other physical deformities and skin features. Detection results can aid in mitigation techniques or be stored for analytics. For example, sea lice detection results can inform targeted treatments comprised of lasers, fluids, or mechanical devices such as a brush or suction.

Methods, systems, and apparatus, including computer programs encoded on computer-storage media, for a lighting controller for sea lice detection. In some implementations, fish are contained within an elliptical tank filled with water. An imaging station located on the elliptical tank is used to capture an image of a fish from which image analysis can be performed to detect sea lice or other skin features, including lesions, on the fish. Pairs of imaging assemblies coordinate pulsing light of at least a first and a second color and capturing images of the fish while the fish is illuminated by at least the first and the second color. By using the captured images with different color light, computers can detect features on the body of a fish including sea lice, skin lesions, shortened operculum or other physical deformities and skin features. Detection results can aid in mitigation techniques or be stored for analytics. For example, sea lice detection results can inform targeted treatments comprised of lasers, fluids, or mechanical devices such as a brush or suction.

The present invention relates to a method and a device for treating and/or transporting food items. The apparatus and method are designed to facilitate treating animals or food items in liquid. The device of the present invention is designed as a spiral shaped channel with one or more channels wound together around an axis. The apparatus of the present invention and the use thereof provides a method to heat or cool food items in a spiral shaped channel device.

The present invention relates to a method of raising fish in a recirculated aquaculture system which includes a fish holding unit in fluid communication with a water supply, the fish holding unit containing a volume of water defining a water depth, and having an osmotic concentration, an oxygen concentration, a temperature, and a pH. The method includes providing a flow of non-recirculated water to the water supply, the non-recirculated water being different from the water in the fish holding unit with respect to the osmotic concentration, the oxygen concentration, the CO2 concentration, the N2 concentration, the NH4+ concentration, the temperature and/or the pH, providing feed pellets, adding the feed pellets to the non-recirculated water and hydraulically transporting the feed pellets to the fish holding unit. The invention also relates to a RAS facility.

An aquarium system includes a tank, a motion sensor, and a light source. The motion sensor is adapted to sense motion within a predetermined distance from the tank. The light source has a controllable intensity projecting light into the tank. The intensity varies responsive to motion sensed by the motion sensor. When the motion sensor senses movement, the light is on at 100% intensity. After some period of no-motion, such as about 60 seconds, the lighting slowly dims to around 20% of full brightness. When it senses movement again, the lighting slowly ramps up to 100% intensity.

An aquarium system includes a tank, a motion sensor, and a light source. The motion sensor is adapted to sense motion within a predetermined distance from the tank. The light source has a controllable intensity projecting light into the tank. The intensity varies responsive to motion sensed by the motion sensor. When the motion sensor senses movement, the light is on at 100% intensity. After some period of no-motion, such as about 60 seconds, the lighting slowly dims to around 20% of full brightness. When it senses movement again, the lighting slowly ramps up to 100% intensity.

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.