An agricultural harvester has a chassis, a non-steerable driving front axle and a rear steering axle with a steering mechanism attached to the chassis. A steerable weight transfer axle has a rear steering axle to weight transfer axle linkage assembly linking the steerable weight transfer axle to the steering mechanism of the rear steering axle. The linkage assembly operates to steer the steerable weight transfer axle in coordination with the rear steering axle. The rear steering axle to weight transfer axle linkage assembly has a rear steer axle pivot arm pivotally connected to the rear steering axle and linked to the steering mechanism of the rear steering axle. The rear steering axle to weight transfer axle linkage assembly also has a reversing pivot linked to the rear steer axle pivot arm and to the steerable weight transfer axle.

The subject matter of the invention is a trackless tugger train (100) having at least one transportation module (10) and at least two axle modules (11), wherein each transportation module (11) is arranged between two axle modules (11), wherein each axle module (11) has a wheel axle (12) and a steering device for steering the wheel axle (12), wherein the steering devices of the axle module (11) are embodied in each case in such a way that each steering device steers the axle module (11) which is assigned to it, independently of a steering device of another axle module (11).

A method is provided for the detection of a critical snaking motion of a trailer of a vehicle combination, in which a setpoint yaw rate of the trailer is ascertained from the transverse acceleration of the trailer and the longitudinal speed of the vehicle combination, the actual yaw rate of the trailer is ascertained using a yaw rate sensor, and by a comparison of the curve over time of the setpoint yaw rate and the actual yaw rate, the presence of a critical snaking motion of the trailer is ascertained.

A transport vehicle includes a chassis with at least two load carriers which are placed next to and at a distance from each other. The distance between the at least two load carriers are modifiable in order to modify the width of the transport vehicle. The at least two load carriers of the transport vehicle are connected to one another by at least one articulated twin-arm structure.

An agricultural harvester has a chassis, a non-steerable driving front axle and a rear steering axle with a steering mechanism attached to the chassis. A steerable weight transfer axle has a rear steering axle to weight transfer axle linkage assembly linking the steerable weight transfer axle to the steering mechanism of the rear steering axle. The linkage assembly operates to steer the steerable weight transfer axle in coordination with the rear steering axle. The rear steering axle to weight transfer axle linkage assembly has a rear steer axle pivot arm pivotally connected to the rear steering axle and linked to the steering mechanism of the rear steering axle. The rear steering axle to weight transfer axle linkage assembly also has a reversing pivot linked to the rear steer axle pivot arm and to the steerable weight transfer axle.

A method for ascertaining an orientation of a trailer relative to a tractor vehicle, wherein the tractor vehicle comprises a detection device which detects a first object region on the trailer and a second object region on the trailer, including recording the first and second regions by the one detection device, providing the recording to an evaluation device, assigning first and second information items to the first and second regions, and determining the orientation of the trailer relative to the tractor vehicle on the basis of the first and second information items by the evaluation device, wherein the evaluation device is configured for recognition in the first and/or second object regions, wherein the component located inside the first and/or second object regions comprises a supporting jack and/or a supporting jack base and/or a reinforcing cross and/or a connecting shaft.

Systems and techniques are provided for simulating movement of an articulated vehicle. An example method can include generating a simulation environment for an autonomous vehicle, wherein the simulation environment includes at least one articulated vehicle that includes a tractor coupled to a first trailer using a first pivot joint; determining a first velocity of the first pivot joint based on a first simulated movement associated with the tractor; and determining a second simulated movement associated with the first trailer based on the first velocity of the first pivot joint and a first distance between the first pivot joint and a first point on the first trailer.

An object of the present invention is to estimate a center-of-gravity position and inertia moment of a trailer and supply the center-of-gravity position and inertia moment for control of an articulated vehicle so as to enable further stabilization of a posture of the articulated vehicle during traveling. A vehicle control device of the present invention is a vehicle control device mounted on a tractor which pulls a trailer, and is provided with: a steering angle control unit that controls a steering angle of wheels of the tractor independently of steering by a driver; and a trailer characteristic estimation unit that estimates a characteristic of the trailer based on a behavior of the tractor during wheel steering by the steering angle control unit.

Orientations of a vehicle with an attached trailer can be specified for obtaining respective images of the trailer. Respective images of the trailer captured by a vehicle camera at the specified orientations can then be received. The images can be input to a machine learning program trained to output trailer size metrics. The vehicle can then be controlled according to the trailer size metrics output from the machine learning program.

A method for controlling steering of a self-powered steerable dolly vehicle during a maneuver, the method comprising determining an articulation angle associated with a drawbar of the dolly vehicle, determining a longitudinal velocity of the dolly vehicle, and controlling the steering of the dolly vehicle based on the articulation angle and on the longitudinal velocity of the dolly vehicle, wherein the controlling comprises initially steering the dolly vehicle in a direction of the articulation angle direction in case the longitudinal velocity of the dolly vehicle is above a velocity threshold.