An automated method for removing tissue from a seed is provided. The automated method includes singulating a seed from a plurality of seeds and imaging the singulated seed to obtain at least one characteristic of the seed. The automated method further includes positioning the singulated seed in a sampler of an automated seed sampling assembly and removing, by the sampler, tissue from the singulated seed based on the at least one characteristic of the seed.

An automated system for sampling seeds generally includes an automated sampling station having a sampler configured to remove material from a seed while protecting germination viability of the seed, a seed conveyor configured to receive the seed from out of the sampling station after the material is removed from the seed, and a sample conveyor configured to receive the material removed from the seed. The sample conveyor is configured to locate the material removed from the seed in a sample container, and the seed conveyor is configured to locate the seed from which the material is removed in a seed container so as to facilitate a one-to-one correspondence between the seed and the material removed from the seed.

Invention is the innovative apparatus to determine plant seeds quality rate in a dormant stage. Aim of the invention is measuring quantity of carbon dioxide radiance on active seeds to calculate average of the germination, the vigor, and a proportion of the value of the light radiated seeds to calculate viable. Apparatus use process of the spectral lighting to warm up seeds to obtain thermal contrasting Infra-red images, to visualize seeds embryos metabolism. The contingent seeds embryos intensity of the radiance is taken in account to determine seeds measurement of the viability, of the vigor indicative. Due to order to create the specimen seed embryo radiometric profile data, recording digital images of the seed unit's specimen data enable to derive, and then calculate the Infra-red contrast value of seed specimen profile. Light titrations of the seeds thermal exposition, due to seeds specimen rotation, eliminate irregularity of the seed layer lighting.

A canola seed sample crusher features a frame, and a drum rotatably carried on the frame and having an array of seed pockets on an outer periphery thereof. The seed pockets are sized and shaped to receive individual canola seeds respectively therein. A pathway is arranged to receive a length of adhesive tape and guide the tape over the seed pockets in the outer periphery of the drum during rotation thereof to adhesively collect the sample of canola seeds from the seed pockets onto the adhesive tape. A crushing mechanism is carried on the frame and operatively installed at a position along the pathway to crush the sample of canola seeds collected on the adhesive tape during passage of the tap tape through the crushing mechanism.

A seed sampling system is provided having an automated seed loading assembly including a seed bin and being operable to singulate seeds from a plurality of seeds within the seed bin. The system also includes an automated seed sampling assembly operable to remove tissue samples from the singulated seeds, and an automated seed transport assembly operable to transfer the singulated seeds from the seed loading assembly to the seed sampling assembly. The seed transport assembly includes multiple retention members. Each of the retention members is movable relative to the seed loading assembly and to the seed sampling assembly. The seed transport assembly is operable to position one of the multiple retention members adjacent to the seed loading assembly for engaging one of the singulated seeds, while positioning another of the retention members adjacent to the seed sampling assembly for presenting another of the singulated seeds to the seed sampling assembly.

To provide an accelerated aging seed testing kit system, a single sheet of plastic or other suitable formable sheet material is pressed into the shape of a compartment base having recesses for mounting a seed holder. A seed holder that includes a seed support and a seed support holder is formed. The seed support holder is formed of a single sheet of plastic having radially extending tabs that fit into the recesses of the container to support the seed support above the rest of the test kit. A lid is formed out of one piece of plastic having a bendable tab to serve as a port and the openings and connecting points of the lid and seed holder are positioned so they can only fit together in one orientation having the port above a bypass channel.

An automated method for operating an automated seed sampling system having a seed loading station, a seed transport subsystem, and a seed sampling station generally includes sensing whether individual seeds are successfully isolated from a bulk of seeds at the seed loading station, and sensing whether the isolated seeds are properly positioned by the seed transport subsystem adjacent the seed sampling station in preparation for removing tissue from the isolated seeds. In some aspects, the method further includes analyzing the tissue removed from the seeds for presence or absence of at least one characteristic, and selecting seeds based on presence or absence of the at least one characteristic.

An automated method for analyzing seeds generally includes collecting image data from individual seeds using a seed sampling system, determining at least one characteristic of each of the individual seeds based on the collected image data, and removing tissue from each of the individual seeds using the seed sampling system. The method also includes, prior to removing the tissue sample from each of the individual seeds, adjusting at least one operational parameter of the seed sampling system based on the at least one characteristic of the seed from which the tissue is to be removed to thereby allow for generally consistent removal of tissue from each of the individual seeds. In some aspects, the method further includes analyzing the tissue removed from the seeds for presence or absence of at least one characteristic, and selecting seeds based on presence or absence of the at least one characteristic.

Provided herein are systems and methods for the automation of seed planting and analysis comprising automated planting of the seeds, germination, and analysis. The methods generally comprise conveying containers containing seeds to an automated seed planting station, wherein each container includes a machine-readable tag, planting at least some of the seeds in the container onto respective planting trays, wherein each planting tray includes a machine-readable tag, allowing the seeds to germinate, and analyzing the germinated seeds. The systems generally comprise a seed planting system and a planting verification and correction system. Also provided herein are backlit templates comprising a light source and a power interface configured to connect to a power source to power the light source.

An agricultural machine includes a seeding system having a seed transport mechanism configured to transport a seed along a transport route. A terahertz-based seed sensor is configured to direct terahertz electromagnetic radiation toward the seed at a sensing location along the transport route and detect terahertz electromagnetic radiation after the terahertz electromagnetic radiation interacts with the seed to provide terahertz data. An actuator is configured to selectively move the seed. A processing system is configured to receive the terahertz data and classify the seed as qualified or non-qualified and to selectively engage the actuator based on whether the seed is classified as qualified or non-qualified.