A system for utilizing waves in an assembly line grow pod includes a plurality of carts, a wave generator and a master controller. The plurality of carts carries a plurality of plants including a first plant and a second plant. The wave generator generates sound waves having a different range of frequency. The master controller is communicatively coupled to the wave generator and comprising a processor and a memory storing a wave recipe and instructions. The wave recipe correlates the plurality of plants with different characteristics of sound waves including frequency. The wave generator generates a first sound wave having the characteristic correlated to the first plant and a second sound wave having the characteristic correlated to the second plant.

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.

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.

An image capture system for a grow pod includes a master controller that has a processor, a memory, and cameras that are communicatively coupled to the master controller and positioned to capture images of plants or seeds. The memory stores a grow recipe and a logic. The grow recipe defines instructions for growing the plants or seeds and expected attributes corresponding to the instructions. The logic, when executed by the processor, causes the master controller to perform at least the following: receive, from the cameras, the images of the plants or seeds, determine attributes of the plants or seeds from the images, compare the attributes of the plants or seeds from the images to the expected attributes defined by the grow recipe, and adjust the instructions of the grow recipe for growing the plants or seeds based on the comparison of the attributes to the expected attributes.

An image capture system for a grow pod includes a master controller that has a processor, a memory, and cameras that are communicatively coupled to the master controller and positioned to capture images of plants or seeds. The memory stores a grow recipe and a logic. The grow recipe defines instructions for growing the plants or seeds and expected attributes corresponding to the instructions. The logic, when executed by the processor, causes the master controller to perform at least the following: receive, from the cameras, the images of the plants or seeds, determine attributes of the plants or seeds from the images, compare the attributes of the plants or seeds from the images to the expected attributes defined by the grow recipe, and adjust the instructions of the grow recipe for growing the plants or seeds based on the comparison of the attributes to the expected attributes.

This invention provides a method and device for disinfecting any products, materials or environment as any complex of physical, chemical, and biotic factors that can include gases, liquids and solids like soil or artificial plant growing media or animals and plants comprising the step of treating them with one or more infrared lights of LED emitters.

Methods and systems for generating a plasma-activated liquid or gas, and applying the plasma-activated liquid for agricultural use. A system embodiment includes a hand-held device that can be pointed and directed at different target areas of a plant. A method embodiment includes generating a plasma discharge in a gas environment or a liquid environment, and applying the gas/liquid to a plant.

Methods and systems for generating a plasma-activated liquid or gas, and applying the plasma-activated liquid for agricultural use. A system embodiment includes a hand-held device that can be pointed and directed at different target areas of a plant. A method embodiment includes generating a plasma discharge in a gas environment or a liquid environment, and applying the gas/liquid to a plant.

A system includes an aerial sensor platform including a spectral imaging device, a position sensor, and an orientation sensor and includes a ground-based sensor platform including at least one soil sensor. The system also includes a computing device with instructions that are executable by a processor to obtain spectral imaging data collected by the spectral imaging device and soil data collected by the at least one soil sensor. The spectral imaging data represents a particular field of view (based on data from the orientation sensor) of a particular geographic region (based on data from the position sensor) of a crop field and the at least one soil sensor is associated with the particular geographic region. The instructions are further executable by the processor to schedule an agricultural activity based on the spectral imaging data and the soil data.

A system includes an aerial sensor platform including a spectral imaging device, a position sensor, and an orientation sensor and includes a ground-based sensor platform including at least one soil sensor. The system also includes a computing device with instructions that are executable by a processor to obtain spectral imaging data collected by the spectral imaging device and soil data collected by the at least one soil sensor. The spectral imaging data represents a particular field of view (based on data from the orientation sensor) of a particular geographic region (based on data from the position sensor) of a crop field and the at least one soil sensor is associated with the particular geographic region. The instructions are further executable by the processor to schedule an agricultural activity based on the spectral imaging data and the soil data.