A spectrometric measuring head for forestry, agricultural and food industry applications comprises a housing having a window and a spectrometer that is arranged inside the housing and comprises a dispersive element and a sensor, a first light source for exposing a sample to light, which reaches the spectrometer through the window after having been transmitted and/or reflected by the sample, and a standard that can be exposed to light to provide a reference for the spectrometer, which standard can be exposed to light by a light source arranged in the housing.

An agricultural work management system includes: a data input unit (41) configured to receive, from an agricultural crop harvester (1), harvesting position data indicating a harvesting work position as agricultural land information, harvest amount data indicating a harvest amount of the agricultural crop harvested in the agricultural land, and quality data indicating the quality thereof as agricultural crop information; a database server (6) configured to store the agricultural land information and the agricultural crop information such that they can be associated with each other; an agricultural work evaluation unit (51) configured to perform agricultural work evaluation on the agricultural land based on the agricultural land information and the agricultural crop information; and a data output unit (42) configured to send out the agricultural work evaluation data generated by the agricultural work evaluation unit.

A method for producing seed corn from the corn plants, for use in growing subsequent corn plants, includes measuring a moisture content of corn kernels on ears of the corn plants in the field and removing, by a combine harvester, the ears of corn from the corn plants when the moisture content satisfies a threshold moisture content. The method then includes separating the corn kernels from cobs of the ears of corn onboard the combine harvester and collecting the separated corn kernels for use as seed corn, whereby one or more subsequent corn plants can be grown from the collected corn kernels.

One or more information maps are obtained by an agricultural work machine. The one or more information maps map one or more agricultural characteristic values at different geographic locations of a field. An in-situ sensor on the agricultural work machine senses an agricultural characteristic as the agricultural work machine moves through the field. A predictive map generator generates a predictive map that predicts a predictive agricultural characteristic at different locations in the field based on a relationship between the values in the one or more information maps and the agricultural characteristic sensed by the in-situ sensor. The predictive map can be output and used in automated machine control.

A harvesting system can include a harvester including a yield monitor system configured to provide information related to a crop-related parameter of a harvested crop material from a harvester sensor and a processing system remote from the harvester and configured to generate processing system-generated data indicative of the crop-related parameter from a processing system sensor. A computing system can be communicatively coupled to the harvester and the processing system. The computing system can be configured to determine a first value for the crop-related parameter at least partially based on harvester-generated data, determine a second value for the crop-related parameter at least partially based on processing system-generated data, determine a difference between the first value and the second value, and generate a correction factor when the difference exceeds a predefined difference range.

A harvest analysis system, intended to be used in a machine (2, 3) for harvesting agricultural products, e.g. combine (2), forage harvester (3) or the like, comprising at least one image acquisition device (4, 40) and at least one processing unit (1), connected to said acquisition device (4, 40) and in turn comprising: at least one memory module (10) in which at least a first reference image is stored; and at least one comparison module (11, 12) configured to perform a comparison between the images of the harvested products, acquired by said device (4, 40) and said reference image.

The present invention discloses a system and method for grading agricultural commodity comprising a moisture sensor, a grain apparatus, a conveyor belt driven by motor, a camera to take plurality of images of the agricultural commodity uniformly distributed on the conveyor belt, a communication device for transmitting information to a processor, which processes the image to ascertain the quality parameters of the agricultural commodity and compares with the standards used for grading, a user interface for displaying the information of grading and a printer to print the information of grading. Further, the moisture sensor provides the moisture reading of a sample of agricultural commodity put through the grain apparatus. Furthermore, the parameters are analyzed using image processing technique and compared with the Standard used for grading of the agricultural commodity to ascertain the grading. Additionally, the system can be integrated or several components at different places connected through network.

A method for growing plants includes both a seeder and a harvester both of which include arrangements for singulating the seeds and for measuring parameters of the seeds while singulated. This can be used for seeding selected seeds and for harvesting particular plants. The system operates by correlating information from the individual seeded seeds and from the harvested seeds in respect of a particular location on the growth medium and may include information relating the growth medium at the location. The location can be determined by seeding the plants in patterns which can be detected by a reader on the harvester. The system can be used to control selection of seeds to take into account soil conditions at the plant.

A method for growing plants includes both a seeder and a harvester both of which include arrangements for singulating the seeds and for measuring parameters of the seeds while singulated. This can be used for seeding selected seeds and for harvesting particular plants. The system operates by correlating information from the individual seeded seeds and from the harvested seeds in respect of a particular location on the growth medium and may include information relating the growth medium at the location. The location can be determined by seeding the plants in patterns which can be detected by a reader on the harvester. The system can be used to control selection of seeds to take into account soil conditions at the plant.

A method for growing plants includes both a seeder and a harvester both of which include arrangements for singulating the seeds and for measuring parameters of the seeds while singulated. This can be used for seeding selected seeds and for harvesting particular plants. The system operates by correlating information from the individual seeded seeds and from the harvested seeds in respect of a particular location on the growth medium and may include information relating the growth medium at the location. The location can be determined by seeding the plants in patterns which can be detected by a reader on the harvester. The system can be used to control selection of seeds to take into account soil conditions at the plant.