A pressure control system includes a sealed area containing one or more carts for growing plant material, the one or more carts movably supported on a track within the sealed area, an air pressure controller operably coupled to the sealed area such that the air pressure controller controls an air pressure within the sealed area, and a controller. The controller includes a processor, a data storage device storing one or more pressure recipes, and a non-transitory, processor-readable storage medium comprising one or more programming instructions stored thereon. The one or more programming instructions, when executed by the processor, cause the processor to: identify the plant material in the one or more carts, retrieve a pressure recipe for the identified plant material from the data storage device, and direct the air pressure controller to adjust the air pressure within the sealed area based on the pressure recipe for the identified plant material.

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.

Systems and methods for programming a grow pod are provided herein. One embodiment of a grow pod includes a plurality of carts for growing plants, a plurality of pod environment affecters, and a pod computing device that, when executed by a processor, causes the grow pod to receive a recipe program. The recipe program may define a grow recipe for the grow pod and may cause actuation of at least a portion of the plurality of pod environment affecters to facilitate growth for the plurality of respective plants. The recipe program may be created via a scripting language that includes a plurality of commands for controlling the grow pod. In some embodiments, the plurality of commands are specific to the grow pod. Embodiments of the grow pod may additionally instantiate a plurality of instances of the recipe program that correspond with each of the plurality of carts.

Disclosed herein is a soil remediation and soil pore stabilising composition comprising at least one electrolyte and at least one cofactor.

Disclosed herein is a soil remediation and soil pore stabilising composition comprising at least one electrolyte and at least one cofactor.

Systems and methods for providing a testing chamber are provided herein. One embodiment of a testing chamber includes a chamber environment affecter and a chamber computing device that includes a processor and a memory component. The memory component may store logic that causes the testing chamber to receive a recipe program, where the recipe program defines a grow recipe for a grow pod. The logic may further cause the testing chamber to determine a difference between operation of the testing chamber and operation of the grow pod, adapt the recipe program for operation by the testing chamber, and execute the recipe program in the testing chamber. The logic may further cause the testing chamber to monitor operation of the testing chamber executing the recipe program to determine a malfunction in the recipe program and provide an indication of the malfunction of the recipe program.

Systems and methods for facilitating communication among grow pods are provided. One embodiment of a system includes a remote computing device that includes a memory component that stores logic. The logic may cause the remote computing device to receive a grow recipe that includes actions for a particular grow pod to grow a plant, implement the grow recipe on the particular grow pod; determine an output of the plant in the particular grow pod using the grow recipe, and determine a random adjustment to the grow recipe. In some embodiments, the logic may cause the computing device to determine an output of the plant in the particular grow pod using the random adjustment to the grow recipe and determine whether the random adjustment to the grow recipe resulted in an improvement in output.

The apparatus (1) for the analysis and management of a field (2), cultivated or intended to be cultivated, comprises: a first detection device (3) adapted for acquiring electromagnetic radiation emitted by vegetation (21) and/or soil (20) of the field (2) and adapted for producing first measurement signals representative of acquisitions performed; a second detection device (4) adapted for spectroscopic analysis of the soil (20) and adapted for producing second measurement signals representative of analyses performed; and a processing unit (6) comprising: a first analysis module (61) configured to obtain first data representative of the vegetation (21) and/or the soil (20) of the field (2), as a function of the first measurement signals; a second analysis module (62) configured to obtain second data of the soil (20) subject to detection, as a function of the second measurement signals; and an evaluation module configured to determine evaluation states of the analysed vegetation and soil, based on the respective first and second data.

Systems and methods for providing an assembly line grow pod are provided. One embodiment of a grow pod includes an exterior enclosure that defines an environmentally enclosed volume, a track that that is shaped into a plurality of helical structures defining a path, and a cart that receives a plant and traverses the track. Some embodiments include a sensor for determining output of the plant, a plurality of environmental affecters that alter an environment of the environmentally enclosed volume to alter the output of the plant, and a pod computing device that stores a grow recipe that, when executed by a processor of the pod computing device, actuates at least one of the plurality of environmental affecters. In some embodiments, the grow recipe alters a planned actuation of the at least one of the plurality of environmental affecters in response to data from the sensor indicating a current output of the plant.