An autonomous path treatment system and associated path treatment method uses a mobile path recording device having a locator, a processor and firmware to capture a sequence of coordinates and directions of travel of a path as the mobile device is moved along the path and generate a path program file. The system also has an autonomous path treatment robot having: a treatment mechanism for treating the path; a controller having a processor and memory storing firmware that when executed obeys steps of the path program file to control the motor and the treatment mechanism to treat the path; and a server configured to execute a path program to process the captured sequence of coordinates and directions into the path program file containing instructions for controlling the autonomous path treatment robot to treat the path based upon the coordinates.

A system and a method are disclosed for planning a path within a field for a farming machine. The system predicts boundaries of the field using a previously captured image of the field and generates a suggested route to be taken by a data collection device based on the predicted boundaries. As the data collection device travels along the suggested route, the data collection device collects location data associated with a current layout of the field. The location data may be labeled with obstructions encountered along the way. Based on the location data, the system identifies current boundaries of the field, which may be different from the predicted boundaries. The current boundaries are sent to a verification device to be verified. After the current boundaries have been verified, the path for the farming machine is planned.

A route generation device generates a route on which a work vehicle travels in a work field by self-driving. The route generation device includes an acquisition processor configured or programmed to acquire information on a basic shape of a target area in which the work vehicle is to perform work in the work field, and a generation processor configured or programmed to generate a work route on which the work vehicle travels and works in the target area by self-driving and to set a work start point of the work route closer to a passing place that is at or adjacent to a boundary of the work field and through which the work vehicle passes when moving from the work field toward a road than a work end point of the work route.

A robot system is used to trace and record boundaries of multiple sites, and data of the recorded boundaries are transmitted to a server for storage therein. The server computes moving paths for the sites based on the data of the recorded boundaries. Upon receipt of a setting signal from a mobile device that indicates a selected robot and a target site, the server transmits a maintenance instruction that includes the boundary and the moving path for the target site to the selected robot, so that the selected robot performs maintenances on the target site based on the maintenance instruction.

An autonomous travel system causes a work vehicle to autonomously travel along an inter-field route preset for a road connecting a field and a field. A travel processor causes the work vehicle to be stopped at a route start position of the inter-field route and to resume autonomous travel when a user is within a predetermined distance from the work vehicle in the field corresponding to the stop position of the work vehicle. An announcement process unit causes the work vehicle to announce travel information about travel on the inter-field route in the field.

An apparatus for controlling a robot is introduced. The apparatus may comprise at least one memory storing at least one instruction, a communication device for communication with at least one server, and at least one processor operatively coupled to the memory. The instruction, when executed by the processor, may enable the apparatus to store a first configuration file received from a first server, where the first file contains information about a first user's robot settings and determine a second configuration file from a second server, different from the first, comprise information about a second user's settings. Based on both configuration files, the apparatus determines a target file containing information about a target setting for controlling the robot. The robot is controlled based on the target information.

An autonomous vehicle control system includes one or more sensors configured for coupling with an agricultural vehicle, the one or more sensors configured to determine kinematics of the agricultural vehicle relative to a crop row. The system includes a guidance control module configured to coordinate steering of one or more steering mechanisms of the agricultural vehicle. The guidance control module includes a sensor input configured to receive kinematics of the agricultural vehicle, a vehicle kinematics comparator configured to determine one or more error values using the received vehicle kinematics, a crop curvature generator configured to determine crop row curvature using the one or more error values, and a steering interface configured to provide instructions to a vehicle steering controller to guide the agricultural vehicle using the crop row curvature.

A combine (work vehicle) is provided with: a positioning unit that obtains a measurement point indicating a position of a vehicle body; an initial external shape generating unit that generates an initial external shape of an agricultural field on the basis of a travel trajectory of the vehicle body constituted of a plurality of measurement points obtained when the vehicle body was manually driven along an external edge of the agricultural field; and an obstacle identification unit that identifies an obstacle for travel on the basis of the travel trajectory and generates an obstacle area including the identified obstacle.

A reception processing unit receives a traveling operation performed by an operator. An acquisition processing unit acquires position information of a work vehicle traveling on a road that connects a field and a field, based on the traveling operation. A generation processing unit generates an inter-field route on which the work vehicle is caused to automatically travel between the field and the field, based on the position information.

A system for autonomous or semi-autonomous operation of a vehicle is disclosed. The system includes a machine automation portal (MAP) application configured to enable a computing device to (a) display a map of a work site and (b) provide a graphical user interface that enables a user to (i) define a boundary of an autonomous operating zone on the map and (ii) define a boundary of one or more exclusion zones. The system also includes a robotics processing unit configured to (a) receive the boundary of the autonomous operating zone and the boundary of each exclusion zone from the computing device, (b) generate a planned command path that the vehicle will travel to perform a task within the autonomous operating zone while avoiding each exclusion zone, and (c) control operation of the vehicle so that the vehicle travels the planned command path to perform the task.