A grain quality sensor comprising a photosite array, an illumination source, a filter, and an electronics module, wherein the illumination source directs light onto a crop sample, wherein the filter limits passage of light into different parts of the photosite array such that certain locations on the photosite array only receive certain wavelengths of light reflected or fluoresced by the crop sample, wherein an electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and the wavelengths of the light received, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of the crop sample.

Methods, systems, apparatus, and articles of manufacture to monitor performance of an agricultural vehicle are disclosed. An example apparatus disclosed herein includes memory, machine readable instructions, and programmable circuitry to execute the machine readable instructions to access an image captured by a camera associated with an agricultural vehicle, determine a harvesting operation metric corresponding to the image, generate interactive display information by storing the image in association with the harvesting operation metric, and cause presentation of the interactive display information via a user interface.

An aspiration system of an agricultural vehicle includes a perforated screen that is configured to be positioned adjacent a fan-cooled fluid cooler, and an air delivery device positioned on one side surface of the perforated screen. The air delivery device includes a series of openings facing the perforated screen for directing air through the perforated screen to dislodge debris on the perforated screen.

A system for removing trash from a flow of harvested crop within an agricultural harvester may include a chopper assembly and a cleaning assembly downstream of the chopper assembly relative to the flow of harvested crop. An upstream side of the cleaning assembly may be positioned closer to the chopper assembly than a downstream side of the cleaning assembly. The cleaning assembly may include a screen and a fan, with the fan positioned at least partially between the upstream and downstream sides of the cleaning assembly. The fan may generate a flow of air in a first direction such that the flow of air passes through the upstream side before the downstream side of the cleaning assembly. Additionally, the screen may be movable along a travel path relative to the fan such that a portion of the screen is movable between the upstream and downstream sides of the cleaning assembly.

A sensor for measuring a thickness of a layer of a grain/residue mixture as the layer is transported through a cleaning arrangement of a combine harvester. The sensor is mounted on a support surface of a grain pan or a sieve of the cleaning arrangement and comprises a tower-shaped support structure with sensor elements attached to the structure and forming a vertical stack of sensor elements, so that a number of sensor elements is submerged in the layer and a number of sensor elements extends above the layer. The sensor elements are configured to measure an electrical property that changes as a function of immediate surroundings of the sensor elements. The sensor elements are configured to be read out independently from each other.

An impact sensor is mounted in a duct of a grain cleaning system above an upper sieve. The impact sensor has an upstream-facing impact-sensing surface with respect to a cleaning airstream, and is configured to transduce impact events and generate impact signals. An electronic control unit (ECU) is configured to generate control signals based upon a particle energy value that is determined from the impact signals. The control signals may serve to adjust various working units of a combine harvester including, by way of example, a cleaning fan and sieves.

A crop mass predictive sensor, comprising an imaging device, a laser-based device such as a LIDAR, a first radar emitting a frequency of energy that is absorbed by plant mass, and a second radar emitting a frequency of energy that passes through plant mass without being absorbed, wherein the imaging device, laser-based device, first radar, and second radar are focused on the crop material in front of an agricultural vehicle, and the information gathered from the imaging device, laser-based device, first radar, and second radar is used to calculate an estimated mass for the crop material that is about to enter the agricultural vehicle.

A grain quality sensor comprising a lens, a filter, a photosite array, an illumination source, and an electronics module, wherein the illumination source directs light containing a known set of wavelengths onto a crop sample, wherein the lens picks up light reflected by the crop sample and directs it into the filter, which allows light to pass into different parts of the photosite array such that certain locations on the photosite array only get certain frequencies of the reflected light, wherein the electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and what frequency the light received was, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of different parts of the crop sample.

A control system for a harvester having a crop cleaner for cleaning a cut crop. The control system includes a processor, a memory, and a human-machine interface. The processor is configured to receive an input corresponding to a desired cleaning level of the crop, monitor the actual cleaning level, and control the crop cleaner based on feedback from monitoring the actual cleaning level to move the cleaning level of the crop towards the desired cleaning level of the crop.

A topographical indication for a field is detected by an aerial sensor and, based on the topographical indication, an area of consistent elevation is calculated. An estimated yield indication for a field is also detected, and an area of consistent estimated yield is calculated. With a controller, a calibration candidate zone is generated, wherein the calibration candidate zone comprises an area of the field with a consistent topography and a consistent estimated yield along a width and a length of the area.