Abstract: The different illustrative embodiments provide an apparatus comprising a landmark controller, a landmark deployment system, and a number of portable landmarks. The landmark controller has a landmark position and placement process. The landmark deployment system has a number of manipulative components. The number of portable landmarks are configured to be deployed to a number of locations within a worksite.

Abstract: The different illustrative embodiments provide a method for generating an area coverage path plan using sector decomposition. A starting point is identified on a worksite map having a number of landmarks. A first landmark in the number of landmarks is identified. A path is generated around the first landmark until an obstacle is detected. In response to detecting the obstacle, the path is made linear to a next landmark. The path is generated around the next landmark.

Abstract: A mobile station for an unmanned vehicle comprises a vehicular storage area for storing a vehicle during transit or at rest. A first wireless transceiver communicates a status or command between the vehicle and the mobile station during at least one of vehicular deployment and rest. A station controller manages a management plan of the vehicle comprising at least one of retooling the vehicle, loading a payload on the vehicle, and recharging or refueling of the vehicle.

Abstract: A system and method for estimating agricultural parameters for growing crops is well suited for promoting efficient utilization of agricultural inputs (e.g., water consumption). Sensors collect data via one or more vehicles equipped with location-determining receivers. A transmitter transmits the collected environmental data to a data processing system. The data processing system applies the collected environmental data to an agronomic model for determining an agricultural management parameter. A prescription is made available for application of an agricultural input (e.g., water) to a crop in a particular location consistent with the collected environmental data and the agronomic model.

Abstract: A method and system for identifying an edge of a crop facilitates guidance of an agricultural machine or other work vehicle along an edge of a crop at an interface between harvested and unharvested portions of a field. A transmitter emits a plurality of a transmitted radiation pattern of one or more generally linear beams spaced apart within a defined spatial zone. A receiver collects an image of the defined spatial zone. A detector detects a presence of crop edge between a harvested and unharvested portion of a field based on an observed illumination radiation pattern on the unharvested portion formed by at least one of the generally linear beams. A data processor identifies coordinate data, in the collected image, associated with the detected crop edge.

Abstract: The different illustrative embodiments provide an apparatus that includes a computer system, a number of structured light generators, and a number of mobile robotic devices. The computer system is configured to generate a path plan. The number of structured light generators is configured to project the path plan. The number of mobile robotic devices is configured to detect and follow the path plan.

Abstract: The different illustrative embodiments provide an apparatus that includes an autonomous vehicle, a modular navigation system, and a number of modular components. The modular navigation system is coupled to the autonomous vehicle.

Abstract: The different illustrative embodiments provide an apparatus that includes an autonomous vehicle, a modular navigation system, and an asymmetric vision module. The modular navigation system is coupled to the autonomous vehicle. The asymmetric vision module is configured to interact with the modular navigation system.

Abstract: A position determining system for a vehicle comprises an imaging unit for collecting image data. A wireless device reads or interrogates a radio frequency identification tag. An identification module determines whether the collected image data contains a visual landmark. A confirmation module determines whether the identified visual landmark is associated with a corresponding radio frequency identification tag having a particular tag identifier. A range finder or distance estimator determines a position offset of the vehicle with respect to the identified visual landmark. A data processor determines a vehicular position of the vehicle based on the determined position offset and a stored reference position associated with at least one of the visual landmark and the radio frequency identification tag.

Abstract: Therefore, the illustrative embodiments provide a computer implemented method and system for providing an application of a resource to plants. A plurality of per plant prescriptions for a plurality of plants are received and a source is selected to fulfill the plurality of per plant prescriptions to form a selected source. Movement of a mobile utility vehicle is controlled to the selected source, the resource is obtained, and movement of the mobile utility vehicle is controlled to each plant in the plurality of plants. The resource is applied from the mobile utility vehicle to each plant according to the per plant prescription.

Abstract: Therefore, the illustrative embodiments provide an apparatus for performing horticultural tasks. In an illustrative embodiment, an apparatus is comprised of a number of data storage devices, a planning process, and a processor unit. The number of data storage devices includes a knowledge base. The processor unit executes the planning process and accesses the knowledge base on the number of data storage devices to identify a horticultural need for a plurality of plants.

Abstract: Therefore, the illustrative embodiments provide a computer implemented method and system for determining individual resource needs for each plant in a plurality of plants. Current conditions are identified using a sensor system. A plurality of per plant prescriptions are calculated for the plurality of plants using the individual resource needs and the current conditions. A resource is obtained from a selected resource source in a number of resource sources. The resource is stored in a mobile utility vehicle and applied from the mobile utility vehicle to each plant in the plurality of plants according to the plurality of per plant prescriptions.

Abstract: The different illustrative embodiments provide a method and system for watering plants. A map of an area is received and a determination is made using a processing unit as to whether the area needs water. If the area needs water, current constraints are identified and a determination is made using the processing system as to whether the current constraints allow for watering. If the current constraints allow for watering, a watering solution application plan is generated using the processing system, and the watering solution application plan is executed using a mobile utility vehicle.

Abstract: Therefore, the illustrative embodiments provide a computer program product comprising a computer recordable media having computer usable program code. Resource needs are determined for each plant in a plurality of plants to form individual resource needs. Conditions are identified in an environment in which the plurality of plants are located by receiving input from a sensor system to form current conditions. A plurality of per plant prescriptions are calculated for the plurality of plants using the individual resource needs and the current conditions. The application of the resource is controlled from a mobile utility vehicle to each plant in the plurality of plants using the plurality of per plant prescriptions.

Abstract: A system and method for estimating agricultural parameters for growing crops is well suited for promoting efficient utilization of agricultural inputs (e.g., water consumption). Sensors collect data via one or more vehicles equipped with location-determining receivers. A transmitter transmits the collected environmental data to a data processing system. The data processing system applies the collected environmental data to an agronomic model for determining an agricultural management parameter. A prescription is made available for application of an agricultural input (e.g., water) to a crop in a particular location consistent with the collected environmental data and the agronomic model.

Abstract: A system and method for estimating agricultural parameters for growing crops is well suited for promoting efficient utilization of agricultural inputs (e.g., water consumption). Sensors collect data via one or more vehicles equipped with location-determining receivers. A transmitter transmits the collected environmental data to a data processing system. The data processing system applies the collected environmental data to an agronomic model for determining an agricultural management parameter. A prescription is made available for application of an agricultural input (e.g., water) to a crop in a particular location consistent with the collected environmental data and the agronomic model.

Abstract: A system or method for monitoring a status of a member of a vehicle comprises a member of a vehicle. A set of one or more magnets is secured to the member. A magnetic field sensor is mounted on a vehicle, spaced apart from the member. The magnetic field sensor produces a data signal. A data processor receives the data signal from the magnetic field sensor and detects at least one of a deformation or movement of the member with respect to the vehicle.

Abstract: A seed sensor system determines the position of the seed relative to the seed tube as the seed passes the sensor. The position of the seed as well as the speed of the planter and the position of the seed tube above the planting furrow are used to calculate trajectory of the seed into the furrow from which the seed spacing is predicated. By sensing the seed in both X and Y directions in the seed tube, the sensor is better able to determine multiple seeds as well providing more precision to the seed population.

Abstract: A system or method for monitoring a status of a member of a vehicle comprises a member of a vehicle. A set of one or more magnets is secured to the member. A magnetic field sensor is mounted on a vehicle, spaced apart from the member. The magnetic field sensor produces a data signal. A data processor receives the data signal from the magnetic field sensor and detects at least one of a deformation or movement of the member with respect to the vehicle.

Abstract: The illustrative embodiments provide a method and apparatus for controlling and coordinating multiple vehicles. In one illustrative embodiment, machine behaviors are assigned to multiple vehicles performing a task. The vehicles are coordinated to perform the task using the assigned behaviors and a number of signals received from other vehicles and the environment during performance of the task. In another illustrative embodiment, a role is identified for each vehicle in a group of vehicles. A number of machine behaviors are assigned to each vehicle depending upon the identified role for the vehicle. The machine behaviors are selected from coordinating machine behaviors stored in a behavior library. Each vehicle is then coordinated to perform the task according to the role and machine behaviors assigned.