A processing system having: a processing unit to execute instructions for processing agricultural data; and a memory to store agricultural data, the processing unit is configured to execute instructions to obtain soil data from at least one sensor of an implement, and to determine, based on the soil data, seed germination data including at least one of time to germination, time to emergence, and seed germination risk for display on a display device.

A processing system having: a processing unit to execute instructions for processing agricultural data; and a memory to store agricultural data, the processing unit is configured to execute instructions to obtain soil data from at least one sensor of an implement, and to determine, based on the soil data, seed germination data including at least one of time to germination, time to emergence, and seed germination risk for display on a display device.

A processing system having: a processing unit to execute instructions for processing agricultural data; and a memory to store agricultural data, the processing unit is configured to execute instructions to obtain properties for seed environment data including at least two of soil color, residue, topography, soil texture and type, organic matter, soil temperature, soil moisture, seed shape and size, seed cold germ, furrow depth, predicted temperature, predicted precipitation, predicted wind speed, and predicted cloud cover, and to determine seed environment data based on the properties.

A processing system having: a processing unit to execute instructions for processing agricultural data; and a memory to store agricultural data, the processing unit is configured to execute instructions to obtain properties for seed environment data including at least two of soil color, residue, topography, soil texture and type, organic matter, soil temperature, soil moisture, seed shape and size, seed cold germ, furrow depth, predicted temperature, predicted precipitation, predicted wind speed, and predicted cloud cover, and to determine seed environment data based on the properties.

Methods and systems are presented for making good use of recently obtained biometric data, for configuring propagule capsules (e.g. containing seeds or spores with growth media and other helpful materials) for deployment via drones so that each has an improved chance of survival, and for configuring drones or piloted craft for safe fleet deployment in remote locations.

Methods and systems are presented for making good use of recently obtained biometric data, for configuring propagule capsules (e.g. containing seeds or spores with growth media and other helpful materials) for deployment via drones so that each has an improved chance of survival, and for configuring drones or piloted craft for safe fleet deployment in remote locations.

A compaction mitigation system for a work area and a method of mitigating compaction in a work area may include determining a compaction map of the work area having compaction data associated with a plurality of reference points, passing a work tool through the work area at the plurality of reference points, and adjusting the work tool at the plurality of reference points based on the compaction data.

A compaction mitigation system for a work area and a method of mitigating compaction in a work area may include determining a compaction map of the work area having compaction data associated with a plurality of reference points, passing a work tool through the work area at the plurality of reference points, and adjusting the work tool at the plurality of reference points based on the compaction data.

A directional garlic seed throwing mechanism includes a base, a rotating device, a vision sensor, a seed throwing guide plate, a seed guide pipe and a plurality of bulbil adjusting devices. The rotating device includes a rotating motor detachably connected to the base and a turntable connected to an output end of the rotating motor. The seed throwing guide plate is arranged on the turntable to enable garlic seeds of seed containing bowls to fall into the seed guide pipe. The seed guide pipe has an upper port right below the bulbil adjusting devices and arranged on the base. An even number of the bulbil adjusting devices are fixed on the turntable uniformly and symmetrically and include the seed containing bowls and bulbil direction control devices for driving the bowls to rotate 180 degrees.

A directional garlic seed throwing mechanism includes a base, a rotating device, a vision sensor, a seed throwing guide plate, a seed guide pipe and a plurality of bulbil adjusting devices. The rotating device includes a rotating motor detachably connected to the base and a turntable connected to an output end of the rotating motor. The seed throwing guide plate is arranged on the turntable to enable garlic seeds of seed containing bowls to fall into the seed guide pipe. The seed guide pipe has an upper port right below the bulbil adjusting devices and arranged on the base. An even number of the bulbil adjusting devices are fixed on the turntable uniformly and symmetrically and include the seed containing bowls and bulbil direction control devices for driving the bowls to rotate 180 degrees.