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 self-moving gardening robot, including a positioning module, a control module, a material cavity, and a working module. The positioning module of the self-moving gardening robot is configured to perform path planning, and the control module controls the self-moving gardening robot to travel according to planned path; and the working module performs a corresponding work when the self-moving gardening robot travels. When the material cavity contains different materials, the self-moving gardening robot may finish different functional tasks based on a same control procedure. In one of embodiments, the self-moving gardening robot is further provided with an accessory interface. By connecting different functional accessories through the accessory interface, the self-moving gardening robot implements multiple functions.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating an auger in a bin to convey a granular treatment material toward a tube, moving the material through the tube with a vacuum toward harvested forage moving in a chute to mix the material with the harvested forage, sensing rotation of the auger; displaying an RPM associated with the sensed auger rotation; displaying a measured harvested forage rate; adjusting the actuator to change the RPM to match the applied material amount to the harvested forage based on the measured harvested forage rate. The system can include a bin having an auger, a sensor that measures auger RPM, a tube, a display that displays the RPM in the cab, and an actuator to adjust applied material by changing the RPM based on a measured harvested forage rate.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating an auger in a bin to convey a granular treatment material toward a tube, moving the material through the tube with a vacuum toward harvested forage moving in a chute to mix the material with the harvested forage, sensing rotation of the auger; displaying an RPM associated with the sensed auger rotation; displaying a measured harvested forage rate; adjusting the actuator to change the RPM to match the applied material amount to the harvested forage based on the measured harvested forage rate. The system can include a bin having an auger, a sensor that measures auger RPM, a tube, a display that displays the RPM in the cab, and an actuator to adjust applied material by changing the RPM based on a measured harvested forage rate.

An agricultural mowing device includes a linkage assembly for attaching to a towing vehicle, and a shaft having an upper end coupled to the linkage assembly for being towed in a field between two adjacent rows of planted matter. The device further includes a primary cutting device mounted to a lower end of the shaft for cutting shorter plant material, and a secondary cutting device mounted near the upper end of the shaft for cutting taller plant material. The device also includes a sensor for sensing a desired cutting height of the planted matter and being communicatively coupled to the primary cutting device or the secondary cutting device, the sensing causing an adjustment along the shaft of the respective one of the primary cutting device or the second cutting device to cut the planted matter at the desired cutting height.

An agricultural combine including a residue spreading system adapted for spreading residue onto a field. The residue spreading system includes a seed container and a seed dispensing system adapted to dispense seeds from the seed container into the residue so that, in operation, the dispensed seeds are spread onto the field together with the residue.

An agricultural combine including a residue spreading system adapted for spreading residue onto a field. The residue spreading system includes a seed container and a seed dispensing system adapted to dispense seeds from the seed container into the residue so that, in operation, the dispensed seeds are spread onto the field together with the residue.

A weed control system includes an autonomous work device, and the autonomous work device includes driving means configured to move the autonomous work device, sensor means configured acquire a sensor signal from the environment of the autonomous device, and a control circuit configured to control the driving means to navigate the autonomous work device in the environment. The weed control system includes at least one disposable releasable shading plate arranged on a release mechanism of the autonomous work device. The control circuit is configured to detect plants in the environment based on the acquired sensor signal, to determine whether a detected plant is a target plant, and in case a detected plant is a target plant, to control the release mechanism to release the releasable shading plate onto the location of the detected target plant.

A weed control system includes an autonomous work device, and the autonomous work device includes driving means configured to move the autonomous work device, sensor means configured acquire a sensor signal from the environment of the autonomous device, and a control circuit configured to control the driving means to navigate the autonomous work device in the environment. The weed control system includes at least one disposable releasable shading plate arranged on a release mechanism of the autonomous work device. The control circuit is configured to detect plants in the environment based on the acquired sensor signal, to determine whether a detected plant is a target plant, and in case a detected plant is a target plant, to control the release mechanism to release the releasable shading plate onto the location of the detected target plant.