A yaw angle measuring device for a separable coupling for fifth wheel couplings includes a sensor element and a measuring arrangement, wherein the sensor element is configured to be arranged on a first coupling partner and the measuring arrangement is configured to be arranged on a second coupling partner, wherein the first coupling partner is configured to be mounted by the coupling arrangement such that the first coupling partner is rotatable about an axis of rotation relative to the second coupling partner, wherein the sensor element generates a measuring signal in the measuring arrangement which serves to determine the yaw angle about the axis of rotation.

A towing assistance apparatus includes an image acquisition unit successively acquiring a rear image and a lateral image serving as a surrounding image captured by an imaging unit that is provided at a towing vehicle to which a towed vehicle is configured to be connected, an angle acquisition unit acquiring a connection angle between the towing vehicle and the towed vehicle, and a display processing unit switching the surrounding image displayed at a display unit from the lateral image to the rear image in a case where the connection angle becomes equal to or greater than a first angle at which a change control for decreasing the connection angle is impossible by a steering of the towing vehicle during a rearward driving thereof in a state where the lateral image is displayed and the towing vehicle to which the towed vehicle is connected is in a rearward driving available state.

A method of controlling tethered self-propelled platforms is provided. The method comprises providing a platform leader and a platform follower connected to the leader with a tether to define a first heading line of the leader and a first coordinate frame of the follower. Each of the leader and the follower is pivotally moveable relative to the tether, defining a leader angle and a follower angle. The method further comprises estimating a predicted position of the leader based on a current position, a current speed, and a current yaw rate of the leader. The predicted position of the leader defines a predicted heading line of the leader. The method further comprises determining a trajectory of the follower from the first coordinate frame to the predicted heading line defining a second coordinate frame of the follower. The trajectory is based on a desired distance the predicted heading line and a desired change in yaw angle of the follower. The method further comprises moving the follower along the trajectory to the second coordinate frame.

A sensor system, for determining an angular change between a utility vehicle and a coupled vehicle trailer, includes a sensor unit having a wheel mounted so as to be rotatable about an axis, and a rotary encoder connected to the wheel and configured to detect a change in position of the wheel. The sensor system further includes a mount having at least one first fixed part configured to connect the sensor system to the utility vehicle or a part thereof, and at least one movable part connected to the sensor unit and mounted so as to be movable on the fixed part. In addition, the sensor system includes a positioning mechanism configured to provide sprung bearing of the movable part in an operating position such that the wheel of the sensor unit can be moved into contact with a vehicle trailer or a part of the vehicle trailer.

A vehicular trailering assist system includes at least one camera disposed at a trailer hitched to a hitch of a vehicle, and an electronic control unit (ECU). The ECU determines, during a first stage of a calibration maneuver of the vehicle and trailer, image coordinates of at least one ground feature point. The ECU, responsive to determining image coordinates of the at least one ground feature point, estimates orientation parameters of the camera based at least on the determined image coordinates and known intrinsic camera parameters. Responsive to estimating the orientation parameters of the camera, and based on the determined parameters of the camera, the ECU determines location of the at least one camera at the trailer.

A controlled steering system includes a sliding carriage attached to the steering at least one steering rod. As the carriage slides from one side of the horizontal pivot pint of the towbar, the direction off steering with respect to the towbar reverses. Also, the distance of the sliding carriage from the horizontal pivot point controls the degree of steering. By controlling the movement of the sliding carriage in response to measurements of towbar angle, the backing process can be partially or completely automated.

Disclosed is a trailer including a bed portion. The bed portion includes a deck, a front extension, and a rear extension. The deck has a first end and a second end. The front extension is slideably engaged with the first end of the deck, and the rear extension is slideably engaged with the second end of the deck. The trailer is a double stretch trailer that is extendable from both ends of the deck. A towing system including a cab and the trailer is also disclosed.

Examples of techniques for controlling a vehicle based on trailer sway are disclosed. In one example implementation according to aspects of the present disclosure, a computer-implemented method includes estimating, by a processing device, an estimated articulation angle between a vehicle and a trailer coupled to the vehicle. The method further includes calculating, by the processing device, an expected articulation angle between the vehicle and the trailer. The method further includes comparing, by the processing device, the estimated articulation angle and the expected articulation angle to determine whether the trailer is experiencing trailer sway. The method further includes, responsive to determining that the trailer is experiencing sway, controlling, by the processing device, the vehicle to reduce the trailer sway.

A towbar controlled steering system is disclosed. A towbar pivots about a pivot point on a wagon front axle, with steering rods connected to steered wheels. At the towbar, the steering rods are attached to a carriage that moves ends of the steering rods in front of (towing position) or behind (backing position) the towbar pivot point. When backing, the wheels are steered in opposite directions as sideways towbar displacement. An automated system senses towbar angle and attenuates steering sensitivity while backing to keep the wagon along a backwards track defined by the tow vehicle.

A control apparatus for a rear wheel steering system is provided to control the rear wheel steering system by calculating a target rear wheel steering angle using sensors included in a parking assist system. The control apparatus includes a first sensor and a second sensor spaced apart from each other and mounted on a rear portion of a vehicle, a determiner configured to determine whether a trailer is mounted at a rear side of the vehicle using the first sensor or the second sensor, and a controller configured to control the rear wheel steering system according to a target rear wheel steering angle calculated using the first and second sensors when it is determined that the trailer is mounted at the rear side of the vehicle.