A particulate material metering system includes a controller configured to determine a radius of curvature of a path of a lead vehicle coupled to an agricultural implement. The controller is configured to determine a lead time of the lead vehicle relative to the agricultural implement based on a speed of the lead vehicle and/or the agricultural implement. The controller is configured to determine a radius of curvature of a path of the agricultural implement based on the radius of curvature of the path of the lead vehicle at a determination time, in which the determination time is a current time minus an offset time, and the offset time is based on the lead time. The controller is configured to determine target particulate material flow rates of respective metering devices of the particulate material metering system based on the radius of curvature of the path of the agricultural implement.

Described herein are systems, methods, and apparatus for agricultural planting including selecting and varying agricultural input types during an in-field operation. In one embodiment, a method calculates a partial addition of seed to a seed pool during planting to minimize or eliminate seeds in the seed pool (520) as a boundary is crossed.

A method for determining setting recommendations for an agricultural spreader includes the steps of: determining an uneven spreading-material distribution in a usable agricultural area or an uneven nutritional status of plants in the usable agricultural area, determining an ideal balancing distribution of spreading material that balances out unevenness of the determined spreading-material distribution in the usable agricultural area or unevenness of the determined nutritional status of the plants in the usable agricultural area, and determining setting recommendations for the agricultural spreader for implementing a balancing distribution of the spreading material, wherein the balancing distribution approximates the ideal balancing distribution.

Agricultural seed planting systems include a processing unit, a frame, a furrow opener coupled to the frame for opening a furrow in soil, and a sensor in communication with the processing unit and adapted to sense a characteristic associated with seed planting. The sensor may generate a signal associated with the sensed characteristic and the processing unit may receive the signal. In some aspects, the sensed characteristic may be either a soil characteristic or a seed characteristic. Information associated with the sensed characteristic can be saved in memory for future use and to assist with more effective planting in the future.

A computer-implemented method of prioritizing agricultural field management includes training a machine learning model using historical machine data, receiving machine data, classifying the machine data, generating an agricultural prescription instruction set; and performing the agricultural prescription instruction set. A computing system includes a processor and a memory storing instructions that, when executed by the processor, cause the computing system to train a machine learning model using historical machine data, receive machine data, classify the machine data, generate an agricultural prescription instruction set; and perform the agricultural prescription instruction set. A non-transitory computer readable medium includes program instructions that when executed, cause a computer to train a machine learning model using historical machine data, receive machine data, classify the machine data, generate an agricultural prescription instruction set; and perform the agricultural prescription instruction set.

The present invention relates to a method for enhancing crop performance in Brassica, the method comprising providing Brassica seeds which have been sorted so that at least 90% of the seed population have a seed diameter of at least 1.7 mm; and seeding said Brassica seeds at a seeding rate sufficient to establish a population of Brassica plants so that the plants have a density of 40 to 95 plants per m.sup.2 when the plants are at any one or more of phenological growth stages 11, 12, 13, 14, or 15, according to the BBCH scale; and that the plants show an establishment rate of at least 40%.

A carrier adjustment assembly for coupling to a frame member of an implement includes a laterally adjustable carrier configured to be coupled to an opener and a first outlet providing at least one nutrient. The assembly further includes a plurality of lateral spacers positioned adjacent to the carrier to laterally adjust the carrier and provide a plurality of adjustment positions. The carrier adjustment assembly facilitates lateral adjustment of the carrier by removal of at least one captively held lateral spacer that sets the lateral adjustment of the carrier, a lateral adjustment of the first outlet, and an adjustment of a lateral separation between a seed row provided by a second outlet and a nutrient row provided by the first outlet.

A system and method that automatically monitors product use, such as the type and amount of agricultural and/or horticultural product stored in and dispensed from a cartridge over time and/or by geographic location. Monitored data are stored in memory such as a tag on the cartridge and may be transmitted to a server for storage, aggregation, and analysis. The cartridge may be authenticated before being authorized for use for the benefit of a current user in dispensing the product. The cartridge may be refilled after confirmation of authorization codes on the cartridge and refilling equipment tags. The cartridge may be calibrated automatically based on the bulk density or other parameter of the product in the cartridge. Data may be aggregated from a plurality of cartridges automatically. As-applied data from individual cartridges may be used to verify, independent of operator input, treated area coverage and product application rate.

In an embodiment, yield data representing yields of crops that have been harvested from an agricultural field and field characteristics data representing characteristics of the agricultural field is received and used to determine a plurality of management zone delineation options. Each option, of the plurality of management zone delineation options, comprises zone layout data for an option. The plurality of management zone delineation options is determined by: determining a plurality of count values for a management class count; generating, for each count value, a management delineation option by clustering the yield data from and the field characteristics data, assigning zones to clusters, and including the zones in a management zone delineation option. One or more options from the plurality of management zone delineation options are selected and used to determine one or more planting plans. A graphical representation of the options and the planting plans is displayed for a user.

A high-efficiency cultivation method for high-frequency drip irrigation, water saving, seedling survival and strengthening, and yield increase of cotton fields in saline-alkali soil is provided, belonging to the field of agricultural planting technologies. It mainly includes performing land preparation; setting a planting mode; laying tubes; performing a high frequency drip irrigation; fertilizing with water; performing intertillage; performing chemical control; and performing green prevention and control. The method effectively solves many defects in the existing methods, improves the quality of cotton field preparation and seeding in saline-alkali soil, saves irrigation water, increases the emergence rate and seedling survival rate, improves the saline-alkali resistance of cotton seedlings, increases the yield, and achieves the goal of water-saving, high-quality and high-efficiency cultivation of cotton seedlings in saline-alkali soil.