Embodiments of the present disclosure provide a humidity and temperature control system for use in the outdoor cultivation of fruits, as typically found in an orchard setting, with the additional aid of a sunshade. Embodiments include a climate control system with an efficient and controlled introduction of water vapor into an outdoor orchard employing a plurality of fogging type nozzles, coupled with an overarching porous solar shade enclosure.

Embodiments of the disclosed technology are directed to a method for combining seed priming and vacuum infiltration to facilitate deep penetration of chemicals or other substances into seeds. By combining the two processes, the germination process of seeds can be started allowing a relatively lengthy period of disinfection. The lengthy period of disinfection under vacuum provides maximum penetration into the seed in order to eradicate diseases occurring deep inside the seed. Any type of seed priming may be used in the disclosed method, including, but not limited to, osmopriming, matrix priming, or hydropriming. Further, any type of seed may be treated, including most vegetable crops, ornamentals, and agronomic crops.

Embodiments of the disclosed technology are directed to a method for combining seed priming and vacuum infiltration to facilitate deep penetration of chemicals or other substances into seeds. By combining the two processes, the germination process of seeds can be started allowing a relatively lengthy period of disinfection. The lengthy period of disinfection under vacuum provides maximum penetration into the seed in order to eradicate diseases occurring deep inside the seed. Any type of seed priming may be used in the disclosed method, including, but not limited to, osmopriming, matrix priming, or hydropriming. Further, any type of seed may be treated, including most vegetable crops, ornamentals, and agronomic crops.

The present disclosure relates to methods and systems for obtaining image information of an organism including a set of optical data; calculating a growth index based on the set of optical data; and calculating an anticipated harvest time based on the growth index, where the image information includes at least one of: (a) visible image data obtained from an image sensor and non-visible image data obtained from the image sensor, and (b) a set of image data from at least two image capture devices, where the at least two image capture devices capture the set of image data from at least two positions.

The present disclosure relates to methods and systems for obtaining image information of an organism including a set of optical data; calculating a growth index based on the set of optical data; and calculating an anticipated harvest time based on the growth index, where the image information includes at least one of: (a) visible image data obtained from an image sensor and non-visible image data obtained from the image sensor, and (b) a set of image data from at least two image capture devices, where the at least two image capture devices capture the set of image data from at least two positions.

Pixel color values representing an image of a portion of a field are received where each pixel color value has a respective position within the image. A processor identifies groups of the received pixel color values as possibly representing a Nitrogen-deficient plant leaf. For each group of pixel color values, the processor converts the pixel color values into feature values that describe a shape and the processor uses the feature values describing the shape to determine whether the group of pixel color values represents a Nitrogen-deficient leaf of a plant. The processor stores in memory an indication that the portion of the field is deficient in Nitrogen based on the groups of pixel color values determined to represent a respective Nitrogen-deficient leaf.

A true leaf and a plurality of artificial leaves are attached on a white reference substrate. A first light source radiates a reference beam of 905 nm while sequentially scanning toward the white reference substrate. A second light source radiates a measuring beam of 1550 nm while sequentially scanning toward the white reference substrate. A threshold level setter/water content index detector calculates a relative water content of a true leaf based on the intensity of each reflection light of the reference beam and the measuring beam which are respectively reflected by the true leaf and a plurality of artificial leaves.

A true leaf and a plurality of artificial leaves are attached on a white reference substrate. A first light source radiates a reference beam of 905 nm while sequentially scanning toward the white reference substrate. A second light source radiates a measuring beam of 1550 nm while sequentially scanning toward the white reference substrate. A threshold level setter/water content index detector calculates a relative water content of a true leaf based on the intensity of each reflection light of the reference beam and the measuring beam which are respectively reflected by the true leaf and a plurality of artificial leaves.

Disclosed is a system for providing plant incubation. An example system may include, a jar having a top opening and a bottom opening, seal lids configured to be removably secured at the top opening or the bottom opening, perforated lids configured to be removably secured at the top opening or the bottom opening, a stand for supporting the jar vertically, and a user computing device. The user computing device is configured to receive data associated with the jar and data associated with the seeds, determine, based on the data, reminders concerning seed planting and times for the reminders, and provide the reminders at the times for the reminders. The reminders including instructions to perform actions with the jar, seal lids, perforated lids, stand, and seeds. The system may further include a smart unit associated with the jar to provide data concerning physical conditions in the jar.

Disclosed is a system for providing plant incubation. An example system may include, a jar having a top opening and a bottom opening, seal lids configured to be removably secured at the top opening or the bottom opening, perforated lids configured to be removably secured at the top opening or the bottom opening, a stand for supporting the jar vertically, and a user computing device. The user computing device is configured to receive data associated with the jar and data associated with the seeds, determine, based on the data, reminders concerning seed planting and times for the reminders, and provide the reminders at the times for the reminders. The reminders including instructions to perform actions with the jar, seal lids, perforated lids, stand, and seeds. The system may further include a smart unit associated with the jar to provide data concerning physical conditions in the jar.