Described herein are technologies that use LIDAR and computer vision to detect locations of receiving vehicles grouped together relative to a forage harvester and detect fill levels of crop material within each receiving vehicle and path and landing position of material expelled from the harvester into a bin of a receiving vehicle of the group. Such information is used as feedback for operating the harvester or one or more self-propelled vehicles moving the receiving vehicles. Some embodiments detect ground level in front of the harvester or the receiving vehicles and use such information as feedback. Some embodiments include a link to communicate the feedback to a GUI for user visualization of the feedback and semi-automated operations. For example, readings from LIDAR and a camera of the harvester detect a position and a crop material fill level for each receiving vehicle in the group, and the GUI outputs the information.

Described herein are technologies that use LIDAR and computer vision to detect a location of a receiving vehicle relative to a forage harvester, fill levels of crop material within the receiving vehicle, and path and landing position of material expelled from the forage harvester and received by a bin of the receiving vehicle. The technologies use such information as feedback for operating the harvester or the receiving vehicle. Some embodiments detect ground level in front of the harvester or the receiving vehicle, and such information is used as feedback too. Some embodiments include a link to communicate the feedback to a GUI for user visualization of the feedback and semi-automated operations of the harvester or the receiving vehicle. For example, readings from LIDAR and a camera of the harvester detect a topography of the material deposited in the bin of the receiving vehicle, and a GUI outputs the topography.

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 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.

In one aspect, a system for detecting crop levels within an agricultural harvester may include an elevator extending between a proximal end and a distal end, with the elevator being configured to carry harvested crops between the proximal end of the elevator and the distal end of the elevator. The system may also include a crop level sensor provided in operative association with the elevator. The crop level sensor may include a sensor body and a paddle pivotably coupled to the sensor body such that the paddle is configured to pivot relative to the sensor body when a crop level of the harvested crops conveyed by the elevator exceeds a threshold crop.

In one aspect, a system for detecting crop levels within an agricultural harvester may include an elevator extending between a proximal end and a distal end, with the elevator being configured to carry harvested crops between the proximal end of the elevator and the distal end of the elevator. The system may also include a crop level sensor provided in operative association with the elevator. The crop level sensor may include a sensor body and a paddle pivotably coupled to the sensor body such that the paddle is configured to pivot relative to the sensor body when a crop level of the harvested crops conveyed by the elevator exceeds a threshold crop.

An automated grain filling system including a sensor and a processor. The sensor is configured to detect at least a portion of an upper perimeter of a receiving container and at least a portion of an upper surface of a grain mound in the receiving container. The processor is configured to compare the detected portion of the upper perimeter and the detected portion of the upper surface, and direct the operation of a grain transfer element. The grain transfer element is configured to transfer grain from a supplying container to the receiving container. The directed operation of the grain transfer element is based at least in part on a result of the comparison of the detected portion of the upper perimeter and the detected portion of the upper surface.

A spout is operably connected to a transferring material for transferring the agricultural material to the receiving vehicle. An imaging device faces towards the storage portion of the receiving vehicle and collects image data. A container module is adapted to determine a container position of the storage portion, or its container perimeter. A spout module is adapted to identify a spout of the transferring vehicle in the collected image data, or to determine a spout position. An alignment module is adapted to determine the relative position of the spout and the container position based on the collected image data and to generate command data or user interface data to facilitate placement of the spout and storage container in relative cooperative alignment for transferring of material from the transferring vehicle to the receiving vehicle.

A spout is operably connected to a transferring material for transferring the agricultural material to the receiving vehicle. An imaging device faces towards the storage portion of the receiving vehicle and collects image data. A container module is adapted to determine a container position of the storage portion, or its container perimeter. A spout module is adapted to identify a spout of the transferring vehicle in the collected image data, or to determine a spout position. An alignment module is adapted to determine the relative position of the spout and the container position based on the collected image data and to generate command data or user interface data to facilitate placement of the spout and storage container in relative cooperative alignment for transferring of material from the transferring vehicle to the receiving vehicle.

An unloading automation system for unloading of harvested crop from an agricultural vehicle, such as a combine harvester, into a container. The container may be part of a vehicle container combination that is arranged to maneuver next to the agricultural vehicle in the field. The unloading automation system includes a filling degree measurement system and position measurement system, wherein the position measurement is based on UWB technology. This non-optical technology improves measurement results in dusty environments. The filing degree measurement system and the position measurement system have at least one UWB tag or base station in common.