A seed imaging system for imaging seeds includes a seed transfer station configured to move seeds through the system. An imaging assembly includes a first camera mounted relative to the seed transfer station and configured to acquire images of the seeds as the seeds move through the system. A second camera is mounted relative to the seed transfer station and is configured to acquire images of the seeds as the seeds move through the system. The second camera has an imaging modality different from an imaging modality of the first camera. First and second cameras may be disposed above and below the seed transfer stations, such as a transparent belt.

Disclosed is a method of priming dry seeds, wherein said seeds firstly wetted in a manner such that the seed absorbs at least 75 wt. % of the amount of water required by the seed for entering phase II of water uptake. Subsequently, the moisture content of the seed is reduced by at least 1 percentage unit, and in manner such that the resulting moisture content of the seed still is at least 25%. At last is the seed incubated in such a manner that: the weight of the seed during the incubation remains at least 80%, such as at least 90% or at least 95%, of the weight of the seed before the incubation; and the moisture content (dry weight based) of the seed during the incubation remains at least 25% during at least 25% of incubation time.

Disclosed is a method of priming dry seeds, wherein said seeds firstly wetted in a manner such that the seed absorbs at least 75 wt. % of the amount of water required by the seed for entering phase II of water uptake. Subsequently, the moisture content of the seed is reduced by at least 1 percentage unit, and in manner such that the resulting moisture content of the seed still is at least 25%. At last is the seed incubated in such a manner that: the weight of the seed during the incubation remains at least 80%, such as at least 90% or at least 95%, of the weight of the seed before the incubation; and the moisture content (dry weight based) of the seed during the incubation remains at least 25% during at least 25% of incubation time.

Methods for preserving viability of plant tissues such as plant embryos are provided herein. Also included are methods for storing genomic DNA and/or molecular marker assay materials in an oil bilayer as part of a high-throughput molecular characterization system. Moreover, plant embryos may be treated while in an oil matrix. The treatment may include chromosome doubling, Agrobacterium-mediated transformation, or herbicide selection as part of an embryo rescue process.

A farming method may be shown and described. In an exemplary embodiment, plants may begin in a germination phase. Next, plants are brought to a nursery for a period of time before optionally being transplanted to one or more subsequent nurseries. Finally, plants are transplanted to a greenhouse where they may grow until they are ready for harvest. In an exemplary embodiment, the nursery phases may be vertical farms while the greenhouse phase may be a traditional, hydroponic, or other type of farm which may receive sunlight. AI may be implemented to optimize environmental conditions and robotics may be used to harvest the plants. Plants may be indexed to efficiently expedite plant growth and optimize the time and plant density/spacing in each phase.

A farming method may be shown and described. In an exemplary embodiment, plants may begin in a germination phase. Next, plants are brought to a nursery for a period of time before optionally being transplanted to one or more subsequent nurseries. Finally, plants are transplanted to a greenhouse where they may grow until they are ready for harvest. In an exemplary embodiment, the nursery phases may be vertical farms while the greenhouse phase may be a traditional, hydroponic, or other type of farm which may receive sunlight. AI may be implemented to optimize environmental conditions and robotics may be used to harvest the plants. Plants may be indexed to efficiently expedite plant growth and optimize the time and plant density/spacing in each phase.

Techniques are described herein for using artificial intelligence to predict crop yields based on observational crop data. A method includes: obtaining a first digital image of at least one plant; segmenting the first digital image of the at least one plant to identify at least one seedpod in the first digital image; for each of the at least one seedpod in the first digital image: determining a color of the seedpod; determining a number of seeds in the seedpod; inferring, using one or more machine learning models, a moisture content of the seedpod based on the color of the seedpod; and estimating, based on the moisture content of the seedpod and the number of seeds in the seedpod, a weight of the seedpod; and predicting a crop yield based on the moisture content and the weight of each of the at least one seedpod.

The present disclosure provides a seed slicer device (100), which includes: a first plate (102) provided with first holes (104); a second plate (106) provided with second holes (108), adapted to fit over the first plate; a sliding plate (110) slidably coupled to a top portion of the second plate, operable to cover the second holes; a third plate (112) provided with a third holes (114), adapted to fit over the second plate; and a cutting assembly (116) coupled to the third plate and adapted to slide over the third holes to provide a slicing action. The seeds are received by the third holes such that at least a first part of the seeds extend beyond the third holes, and, upon actuation of the cutting assembly, the seeds are cut by the cutting means to divide the seeds into corresponding first parts and second parts.

A quilted composite sheet containing seeds makes growing microgreens and other crops simple. Each sheet is a layered composite of multiple materials including seed, grow substrate and seed cover. A user can spread a seed quilt over the surface to be planted, water, wait, and harvest.

Kits for seed pre-germination are included. The kit includes a storage vessel and a seeding composition. The seeding composition includes plant seeds, a porous granular material, and a polymer-coated fertilizer. Methods for preparing seeds for germination are also included. The method includes combining the seeding composition with water in the storage vessel and sealing the storage vessel, such that little to no aeration is permitted during subsequent storage of the same.