Abstract: Crops, for example microgreens, may be aeroponically grown from seed on substrates. The substrates may be seeded with the substrates in a horizontal position, and then arranged vertically for germination and further growth. A gelling material in solution, with the gelling material for example a gellum, may be applied to the substrates, while in the horizontal position, so that the seeds are retained on the substrates when the substrates are moved to a vertical position.

Abstract: A gel plug comprised of a gel may be used for growth of plants. The gel may include two polysaccharide components, with a second of the two components providing increased rigidity Plants may be grown, including from seed, in the gel plug.

Abstract: An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

Abstract: Crops, for example microgreens, may be aeroponically grown from seed on substrates. The substrates may be seeded with the substrates in a horizontal position, and then arranged vertically for germination and further growth. A gelling material in solution, with the gelling material for example a gellum, may be applied to the substrates, while in the horizontal position, so that the seeds are retained on the substrates when the substrates are moved to a vertical position.

Abstract: An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

Abstract: An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

Abstract: A gel plug comprised of a gel may be used for growth of plants. The gel may include two polysaccharide components, with a second of the two components providing increased rigidity Plants may be grown, including from seed, in the gel plug.

Abstract: An aeroponic crop growing system may include a plurality of vertical walls configured to grow plants extending through the walls. Drains may allow for drainage of excess water, with the drains providing the excess water to gutters. In some embodiments the gutters are positioned below a floor under the walls, with the floor including gaps for passage of the water from the drains of the walls to the gutters. In some embodiments the gaps in the floor, gutters, and walls may be repositionable. In some embodiments the floor may be of modular components, which may allow for drainage of excess liquid for a variety of different grow wall configurations.

Abstract: A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

Abstract: A bracket for holding a plurality of plant receptacles for use in an automated systems in an aqueous farming system that provides an under-canopy circulation system.

Abstract: A gel plug comprised of a gel may be used for growth of plants. The gel may include two polysaccharide components, with a second of the two components providing increased rigidity Plants may be grown, including from seed, in the gel plug.

Abstract: A substrate comprised of a gel on a wire or mesh scaffolding may be used for growth of plants. The gel may include two polysaccharide components, with a second of the two components providing increased rigidity and/or adherence to the scaffolding. Plants may be grown, including from seed, in the substrate. The substrate may be used as part of a grow wall in an aeroponics plant growth system.

Abstract: An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

Abstract: Crops, for example microgreens, may be aeroponically grown from seed on substrates. The substrates may be seeded with the substrates in a horizontal position, and then arranged vertically for germination and further growth. A gelling material in solution, with the gelling material for example a gellum, may be applied to the substrates, while in the horizontal position, so that the seeds are retained on the substrates when the substrates are moved to a vertical position.

Abstract: A bracket for holding a plurality of plant receptacles for use in an automated systems in an aqueous farming system.

Abstract: An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

Abstract: A dual-media horticultural plug comprising a base having a substantially continuous bottom surface and a top surface spaced from the bottom surface, a sidewall extending from the base and forming an elongated inner cavity, a growing substrate substantially filling the elongated inner cavity, and a water-impermeable outer cover substantially covering an open top end of the elongated inner cavity. The growing substrate comprises a first growing medium having a first water holding capacity, and at least one of the base and the sidewall comprise a second growing medium having a second water holding capacity. The first water holding capacity is greater than the second water holding capacity.

Abstract: A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

Abstract: A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.

Abstract: A plant growing system comprising a growing panel and a porous air hose coupled to the growing panel. The growing panel includes a plurality of openings for receiving a plurality of plant receptacles. The plurality of openings are arranged in a plurality of parallel lines on the growing panel, and the porous air hose extends along the growing panel between at least two of the parallel lines.