An agricultural data system comprising at least one stalk sensor disposed on a harvester configured to sense incoming crop stalks, at least one processor in communication with the at least one stalk sensor, and a display in communication with the at least one processor, wherein the processor is configured to align as-planted data with as-harvested data from the at least one stalk sensor.

The disclosed apparatus, systems and methods relate to devices, systems and methods for reducing cross-track error in harvesting row crops such as corn. A cross track error system including a corn head, a row unit disposed on the corn head. The row unit including a set of stripper plates, a resilient member disposed proximal to the stripper plates, a sensor unit in communication with the resilient member, and a processor. The processor is constructed and arranged to process signals generated by the sensor unit in response to deflection of the resilient member.

An agricultural harvester includes a frame and a crop cleaning assembly supported on the frame. The crop cleaning assembly, in turn, includes an oscillating component configured to oscillate relative to the frame in a manner that conveys crop material across the oscillating component. Furthermore, the agricultural harvester includes a RADAR sensor configured to emit an output signal directed at the crop material present on the oscillating component and detect an echo signal reflected by the crop material present on the oscillating component. Additionally, the agricultural harvester includes a computing system communicatively coupled to the RADAR sensor. In this respect, the computing system is configured to determine a thickness of the crop material present on the oscillating component based on detected echo signal.

A harvesting machine has a controlled subsystem that performs harvesting machine functionality, and a control system that controls the controlled subsystem. A header is mounted to the harvesting machine and has row dividers (that divide rows of crop stalks) and gathering chains. A set of crop loss inhibitors is mounted proximate a forward portion of each of the gathering chains, in a direction of travel of the harvesting machine. The crop loss inhibitors also include a sensor that senses a variable, indicative of a crop attribute, as each crop stalk passes through the set of crop loss inhibitors.

A row unit for a header of an agricultural harvester is provided. The row unit includes a frame, a first deck plate assembly mounted to the frame, and a second deck plate assembly mounted to the frame. The first and second deck plate assemblies each include a deck plate, a plurality of deck plate segments extending from the deck plate and moveable between a first position and a second position relative to the deck plate, and a plurality of biasing members for biasing each respective deck plate segment. The row unit includes both operator controlled macro adjustment and automatic micro adjustment of a gap between the first deck plate assembly and the second deck plate assembly. The micro adjustment is achieved through biasing members biasing each respective deck plate segment.

A row crop header for a harvester having a subframe removably coupleable to a feeder housing of the harvester. A pivot assembly is supported by the subframe permitting first and second header sections to pivotably move between raised and lowered positions together or independently of the other. A cross-auger center suspension assembly rotateably supports one end of the first cross-auger section and one end of the second cross-auger section as the first and second header sections pivotally move between the raised and lowered positions.

The invention relates to a system for adjusting the height of an agricultural implement, including an arm that can be controlled so as to raise and lower the implement; a height measuring sensor mounted on the arm and positioned in front of the implement in the direction of travel of the vehicle equipped with the arm. A calculator configured to provide a control set point for the height of the arm on the basis of the measurements obtained by the sensor, wherein the sensor is a light screen device formed by an emitter in the form of a column of light sources and a receiver in the form of a column of photoreceptors. The emitter and the receiver are mounted on the arm facing one another and extending along their longitudinal axis, perpendicularly to the ground, in order to measure the height of plants located therebetween.

A harvesting head yield monitor comprises two sensing elements (328, 330) respectively disposed in two adjacent row unit covers (114). A driver circuit (400) drives one of these sensing elements (328) to produce a high radio frequency signal. The other sensing element (330) receives the signal. A signal conditioning circuit (402) receives the signal from the other sensing element. A controller (404) coupled to the signal conditioning circuit converts the received signal into a signal that indicates the crop yield of the row unit that is disposed underneath the two adjacent row unit covers.

A row unit of an agricultural harvester is disclosed for the automatic adjustment of a gap size of the row unit stripping plates. The row unit includes first and second longitudinally extending stripping plates mounted on a frame and having opposed stripping edges which define a gap between them. The row unit further includes a gap adjustment mechanism for adjusting a size of the gap between the first and second stripping plates. The gap adjustment mechanism includes a control arm, a rocker assembly operatively connected to one of the first and second stripping plates and slidably connected to the control arm, and a biasing member for biasing the rocker assembly along the control arm toward a predetermined position corresponding to a predetermined gap size.

A plant by plant harvester is provided. The harvester may harvest and analyze single or double rows of crops. The single row harvester may have a first and a second guide unit which surrounds a single row of a crop and directs the single row of the crop into a sheller, picker, or grain/fruit separation unit. In an alternative embodiment of the device, the device may harvest two rows of crops. A GPS or any other location positioning device having an antenna is secured to the top of the main frame and allows the harvester to be remotely controlled. A hopper, container or holding bin may, in real-time, calculate the weight of the separated products. A plurality of sensors may be located on or near the first and/or second guide unit which allows the harvester to, for example, capture data related to the crop at the single plant level.