An agricultural harvester includes a crop processor for reducing crop material to processed crop, an unload conveyor for transferring a stream of processed crop out of the agricultural harvester, a camera for capturing images of an area proximate the agricultural harvester, and one or more computing devices. The one or more computing devices receive the image data from the camera, identify, from the image data, a pre-determined visual marker corresponding to a receiving vehicle, determine, from the visual marker, a location of the receiving vehicle relative to the agricultural harvester. The one or more computing devices also generate automated navigation data based on the location of the receiving vehicle relative to the agricultural harvester, the automated navigation data to automatically control operation of at least one of the agricultural harvester and the receiving vehicle to align the unload conveyor with a grain bin of the receiving vehicle.

An agricultural harvester includes a crop processor, an unload conveyor and first and second a first electromagnetic detecting and ranging modules. One or more computing devices are configured to receive first data from the first electromagnetic detecting and ranging module, the first data indicating the location of a receiving vehicle relative to the agricultural harvester, receive second data from the second electromagnetic detecting and ranging module, the second data indicating at least one of a fill level and a distribution of grain in the receiving vehicle, and generate automated navigation data based on the first data and the second data, the automated navigation data to automatically control operation of at least one of the agricultural harvester and the receiving vehicle to align the unloading conveyor with the receiving vehicle.

A harvester includes a first electromagnetic detecting and ranging module for detecting the location of a receiving vehicle and a second electromagnetic detecting and ranging module for detecting at least one of a fill level and a distribution of processed crop in a grain bin of the receiving vehicle. One or more computing devices are configured to receive first data from the first electromagnetic detecting and ranging module, receive second data from the second electromagnetic detecting and ranging module and use the first data and the second data to generate graphic data defining a graphical representation illustrating the relative positions of an unload conveyor of the harvester and the grain bin and illustrating at least one of a fill level and a distribution of processed crop in the grain bin. An electronic device is configured to use the graphic data to present the graphical representation on a graphical user interface.

An agricultural harvester includes an electromagnetic detecting and ranging module for detecting a location of an object relative to the agricultural harvester and a camera for capturing images of an area within a field of view of the electromagnetic detecting and ranging module. One or more computing devices receive first data from the electromagnetic detecting and ranging module, the first data indicating the location of the object relative to the agricultural harvester, receive image data from the camera and use the image data to determine whether the object is a receiving vehicle. If the object is a receiving vehicle, the one or more computing devices use the first data and the second data to generate graphic data defining a graphical representation illustrating the relative positions of the unload conveyor and the receiving vehicle. An electronic device including a graphical user interface presents the graphical representation on the graphical user interface.

An agricultural harvester includes a crop processor, a grain tank, an unload conveyor, and an electromagnetic detecting and ranging module positioned at or above a top of the grain tank for detecting a fill level of the grain tank and the location of a receiving vehicle relative to the combine harvester. One or more computing devices receive data from the electromagnetic detecting and ranging module, the data indicating the fill level of the grain tank and the location of the receiving vehicle relative to the combine harvester, and use the data to generate graphic data defining a graphical representation illustrating the relative positions of the unload conveyor and a grain bin of the receiving vehicle. An electronic device including a graphical user interface presents the graphical representation on the graphical user interface.

A camera captures an image of a portion of a cart and accesses stored maps that map visual features of carts to a set of settings that are applied to an automatic fill control system. A map that matches visual features of the cart, in the captured image, is identified and the settings in that map are applied to the automatic fill control system.

A sensor detects a variable indicative of a position of a receiving vehicle relative to a harvester during a harvester operation in which a material conveyance subsystem on the harvester is conveying harvested material to the receiving vehicle. If the receiving vehicle is in a compromised position in which it is out of range of the material conveyance subsystem or is about to be out of range, then a control signal is generated that can alert the operator of the harvester, automatically control harvester speed, or perform other control operations.

A harvester monitoring system configured to determine one or more parameters associated with harvested items, the system comprising: a camera module having a field of view and configured to generate image data associated with the harvested items; a mounting bracket configured to secure the camera module to a harvester such that a conveyor of the harvester is within the field of view of the camera module; a location sub-system configured to determine and output location data representative of a geographical location of the harvester monitoring system; and a processing unit configured to receive the image data and the location data, to determine one or more parameters associated with the harvested items, and to record the one or more parameters in association with the location data on a computer readable medium.

A harvester including a mono-camera having a first field of view, where the camera outputs a first image representative of the first field of view, and where the first image is a two-dimensional representation of the first field of view. The harvester also includes a controller in operable communication with the mono-camera, where the controller establishes a second two-dimensional reference frame fixed relative to the first field of view, where the controller identifies a reference point within the first image, where the controller locates the reference point within the second two-dimensional reference frame, and where the controller calculates the location of the reference point relative to the first, three-dimensional reference frame based on the position of the reference point within the second two-dimensional reference frame.

A camera captures an image of a portion of a cart and accesses stored maps that map visual features of carts to a set of settings that are applied to an automatic fill control system. A map that matches visual features of the cart, in the captured image, is identified and the settings in that map are applied to the automatic fill control system.