A system and method are provided for the indoor and outdoor cultivation of larger fruiting plants. Improved lighting techniques, plant layouts, and space utilization are provided to improve the quality and yields of harvested products from large fruiting plants on a per plant and unit area basis. The uniformity of artificial light is improved from the top to the bottom of tall plants and vines, and overcome the lack of light penetration through the canopy of the plant by changing the orientation of lights from a horizontal to vertical alignment along the side of the plant verses over the top of the canopy, as well as increasing the number of light sources to reduce shading. Plants are trained to grow in specific directions and orientations in a grid system to enable an optimal and uniform light distribution and to improve space utilization in a given growing area.

Automated terrariums and methods of using the terrariums are disclosed. The automated terrarium comprises a housing having a base and a lid, wherein the lid is supported by at least two support pillars. The terrarium also comprises at least two transparent side panels supported by the at least two support pillars and positioned between the base and the lid, an irrigation system within the base, a lighting system within the lid, and a control unit. The control unit is adapted to monitor growth of the plant and adjust the irrigation system, heating system, airflow system, and/or lighting system.

An agricultural stake to support plant includes a fiberglass reinforced plastic (FRP) elongated member comprising a top end and a bottom end, and an exterior coating impregnated with an aggregate covering an exterior surface of the elongated member. The exterior coating is configured to provide purchase to a line attached to the elongated member. A cap may be secured over the top end of the elongated member and is configured to withstand a force used to drive the elongated member into a ground surface.

A window planter includes a first compartment including a first sidewall and a second sidewall. The first compartment is configured to house a first group of plants. A second compartment is slidably coupled to the first compartment. The first compartment includes a first outer sidewall. The second compartment is configured to house a second group of plants separated from the first group of plants by the first sidewall of the first compartment. A third compartment is slidably coupled to the first compartment. The third compartment includes a second outer sidewall. The third compartment is configured to house a third group of plants separated from the first group of plants by the second sidewall. At least the first compartment and the second compartment are configured to be secured to a window frame.

A window planter includes a first compartment including a first sidewall and a second sidewall. The first compartment is configured to house a first group of plants. A second compartment is slidably coupled to the first compartment. The first compartment includes a first outer sidewall. The second compartment is configured to house a second group of plants separated from the first group of plants by the first sidewall of the first compartment. A third compartment is slidably coupled to the first compartment. The third compartment includes a second outer sidewall. The third compartment is configured to house a third group of plants separated from the first group of plants by the second sidewall. At least the first compartment and the second compartment are configured to be secured to a window frame.

The plant cultivation device which workability of cutting of the leaves of the plant at the base portion thereof from the root portion of the plants. The plant cultivation device includes a culture medium holding portion in a cylindrical shape, accommodating and holding a seedling culture medium, arranged in the through-holes of the fluid passage member and absorbing the culture fluid into the seedling culture medium and a leaf supporting portion formed in a cylindrical shape, arranged at an upper side of the culture medium holding portion and supporting the leaves from around the leaves which are cultivated from the seeds. The culture medium holding portion and the leaf supporting portion are formed such that a cutting tool, used for separation between the seedling culture medium and the leaves, can be insertable from outside into a bordering portion between the culture medium holding portion and the leaf supporting portion.

The plant cultivation device which workability of cutting of the leaves of the plant at the base portion thereof from the root portion of the plants. The plant cultivation device includes a culture medium holding portion in a cylindrical shape, accommodating and holding a seedling culture medium, arranged in the through-holes of the fluid passage member and absorbing the culture fluid into the seedling culture medium and a leaf supporting portion formed in a cylindrical shape, arranged at an upper side of the culture medium holding portion and supporting the leaves from around the leaves which are cultivated from the seeds. The culture medium holding portion and the leaf supporting portion are formed such that a cutting tool, used for separation between the seedling culture medium and the leaves, can be insertable from outside into a bordering portion between the culture medium holding portion and the leaf supporting portion.

A plant support system includes a support ring having at least one wall portion, and at least one support beam coupled to the at least one wall portion and configured to increase rigidity of the at least one wall portion. Further, the plant support system also includes a base coupled to the at least one wall portion and having at least one stationary clamping surface; a clamp spine having a movable clamping surface situated opposite the at least one stationary clamping surface; and a plurality of spring leaves coupled to the clamp spine and configured to bias the clamp spine.

A plant support system includes a support ring having at least one wall portion, and at least one support beam coupled to the at least one wall portion and configured to increase rigidity of the at least one wall portion. Further, the plant support system also includes a base coupled to the at least one wall portion and having at least one stationary clamping surface; a clamp spine having a movable clamping surface situated opposite the at least one stationary clamping surface; and a plurality of spring leaves coupled to the clamp spine and configured to bias the clamp spine.

An automated plant training system and related methods are designed to train medium to tall plants to grow in a height restricted space by adjusting the plant's direction of growth through the use of phototropism. The device can physically control the plant's main stem, branches and foliage from excessive vertical growth.