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 combine harvester includes a crop material sensor arrangement having a crop material sensor configured to monitor crop material downstream of a threshing and separating system of the combine, and having a sensor window through which the crop material sensor monitors the crop material. The sensor window is arranged adjacent to a flow path of the crop material such that crop material flows past the sensor window as it flows along the flow path, and the sensor window is arranged such that an angle is formed between a plane defined by the sensor window and a tangential projection that extends from a component of the combine harvester that influences the flow path immediately upstream of the sensor window. This ensures that the camera window remains sufficiently clean to allow the crop material sensor to monitor crop material through the window.

A controller for controlling a chopper arrangement of an agricultural harvester. The controller receives sensor data indicative of an intensity of chopping performed on crop material by the chopper arrangement, and sensor data indicative of a power consumption of the chopper arrangement. The controller has a processor to determine an actuator setting for a chopper arrangement actuator of the agricultural harvester in dependence on the received sensor data indicative of the intensity of chopping and the received sensor data indicative of the power consumption. The controller sends an actuator control signal to the chopper arrangement actuator to control the chopper arrangement actuator to operate in accordance with the associated determined actuator setting. The determined actuator setting includes an amount of insertion, and an angle of insertion, of at least one bank of counter knives of the chopper arrangement relative to rotatable knife rows of the chopper arrangement.

A controller for controlling a chopper arrangement of an agricultural harvester. The controller receives sensor data indicative of an intensity of chopping performed on crop material by the chopper arrangement, and sensor data indicative of a power consumption of the chopper arrangement. The controller has a processor to determine an actuator setting for a chopper arrangement actuator of the agricultural harvester in dependence on the received sensor data indicative of the intensity of chopping and the received sensor data indicative of the power consumption. The controller sends an actuator control signal to the chopper arrangement actuator to control the chopper arrangement actuator to operate in accordance with the associated determined actuator setting. The determined actuator setting includes an amount of insertion, and an angle of insertion, of at least one bank of counter knives of the chopper arrangement relative to rotatable knife rows of the chopper arrangement.

A method is provided for controlling a threshing system for an agricultural harvester. The method includes using a camera for obtaining images of a crop flow, processing the obtained images and controlling an operational setting of the threshing system. The images are obtained downstream of the threshing system, preferably somewhere between the threshing rotor or threshing drum and the residue spreader. The image processing aims at detecting grain ears in the obtained images, and to derive from those images at least one physical property of the detected grain ears. The operational setting of the threshing system are controlled in dependence of the derived at least one physical property.

Methods and systems for mapping the distribution of residue material in an environment in which one or more agricultural machines are operable. A sensing arrangement including one or more sensors mounted or otherwise coupled to an agricultural machine operating within the environment is used to obtain sensor data indicative of residue material spread by a spreader tool of the machine. A local distribution of material associated with the spreader tool is determined and used to update a map of a global distribution of the material across the environment. The map of the global distribution comprises one or more sub-regions categorized based on the local distribution dependent on material characteristics at those sub-regions.

Methods and systems for mapping the distribution of residue material in an environment in which one or more agricultural machines are operable. A sensing arrangement including one or more sensors mounted or otherwise coupled to an agricultural machine operating within the environment is used to obtain sensor data indicative of residue material spread by a spreader tool of the machine. A local distribution of material associated with the spreader tool is determined and used to update a map of a global distribution of the material across the environment. The map of the global distribution comprises one or more sub-regions categorized based on the local distribution dependent on material characteristics at those sub-regions.

Systems and methods for mapping the distribution of residue material in an environment in which one or more agricultural machines are operable. A sensing arrangement having one or more sensors mounted or otherwise coupled to an agricultural machine operating within the environment is used to obtain sensor data indicative of residue material spread by a spreader tool of the agricultural machine. From this a local distribution of residue material associated with the spreader tool is determined which is used to update a map of a global distribution of the residue material across the environment. The map comprises a grid-based map having a plurality of cells corresponding to sub-regions within the environment, wherein a value associated with each cell is representative of a measure of the residue material present within the corresponding sub-region.

An agricultural harvester includes a frame, a feeder coupled to the frame, and a harvesting implement coupled to the feeder. Additionally, the agricultural harvester includes an actuator configured to rotate the harvesting implement relative to the frame between a non-turned position and a turned position. Moreover, the agricultural harvester includes a sensor configured to capture data indicative of a turn being made by the agricultural harvester and a computing system communicatively coupled to the sensor. In this respect, the computing system is configured to determine a magnitude of the turn based on the data captured by the sensor. In addition, the computing system is configured to compare the determined magnitude of the turn to a minimum threshold value and, when the determined magnitude exceeds the minimum threshold value, control the operation of the actuator such that the harvesting implement is rotated to the turned position.

An agricultural harvester includes a frame, a feeder coupled to the frame, and a harvesting implement coupled to the feeder. Additionally, the agricultural harvester includes an actuator configured to rotate the harvesting implement relative to the frame between a non-turned position and a turned position. Moreover, the agricultural harvester includes a sensor configured to capture data indicative of a turn being made by the agricultural harvester and a computing system communicatively coupled to the sensor. In this respect, the computing system is configured to determine a magnitude of the turn based on the data captured by the sensor. In addition, the computing system is configured to compare the determined magnitude of the turn to a minimum threshold value and, when the determined magnitude exceeds the minimum threshold value, control the operation of the actuator such that the harvesting implement is rotated to the turned position.