Methods and apparatus are provided for performing an assisted driving trailer reversing operation including a camera operative to capture an image, an interactive user interface operative to display a graphical user interface and to receive a user input, a processor operative to generate the graphical user interface in response to the user input, the user input being indicative of a trailer destination, to generate a left maneuverability margin and a right maneuverability margin in response to a trailer dimension and a hitch angle, and a projected trailer path in response to the trailer destination, wherein the graphical user interface includes the image and a plurality of graphics overlaid on the image indicative of the left maneuverability margin, the right maneuverability margin, the projected trailer path and the trailer destination, and a vehicle controller operative to perform a trailer reversing operation in response to the control signal.

A railless tugger train (100) includes a train module (10), at least one transportation module and at least two axis modules, wherein each axis module has a stiffly configured axis beam, at which a first mounting device is configured in the form of a stiff mounting of the train module or a transportation module and at which a second mounting device is configured for an articulated connection of a transportation module. At least two wheels (19) are mounted at the axis beam in such a way that the wheels are each rotatable around a rotation axis (D) which is configured vertical to the longitudinal axis (L) of the axis beam.

Systems and methods for coordinating and providing steering assistance between towing vehicles and towed vehicles during towing events. The towing steering assistance may be provided by the towed vehicle in the form of assistive steering maneuvers to assist the towing vehicle with turning during the towing event. The assistive steering maneuvers may be provided to account for turning maneuvers, steering compensation, and stability events of the coupled vehicles during the towing events, for example.

A driver assistance device according to an embodiment includes a coupling angle acquirer that acquires a coupling angle between a towing vehicle and a towed vehicle coupled to the towing vehicle; and a notifier that issues a given notification in the towing vehicle when the towing vehicle is driven with the towing vehicle and the towed vehicle differing in orientation at a given value or more based on the coupling angle, the towing vehicle moves in a given distance or less while maintaining a steering angle, and the steering angle of the towing vehicle enables the towing vehicle and the towed vehicle to be placed in a serial state with the towing vehicle and the towed vehicle substantially matching with each other in orientation.

A method for reversing an articulated vehicle comprising a tractor and one or more towed vehicle units, the method comprising arranging an electrified trailer (e-trailer) comprising one or more electric machines (EMs) and a steering function as a rearmost towed vehicle unit of the articulated vehicle, obtaining a reversal command indicative of a desired reversal maneuver by the articulated vehicle, configuring the e-trailer in a reverse towing mode of operation, wherein the e-trailer uses the one or more EMs and the steering function to reverse according to the reversal command while towing the tractor and any further trailer units of the articulated vehicle, configuring the tractor and the further trailer units of the articulated vehicle in a passive towed mode of operation, wherein the tractor and the further trailer units are towed by the e-trailer, and reversing the articulated vehicle by issuing the reversal command to the e-trailer.

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.

An optimal lane keeping assistance device of an articulated vehicle (100), in which a tractor (200) and a trailer (300) are connected via a fifth wheel coupling (400), includes a first sensor (520,540) which detects a tractor state variable, a second sensor (560) which detects a fifth wheel coupling (400) state variable, and an electric control unit (500) incorporating a microcomputer. The electric control unit (500) calculates a control variable (Uc) according to a target lateral displacement value (Yd), an output signal of the first sensor (520, 540), and an output signal of the second sensor (560), taking into account a feedback gain of an optimal control rule, to calculate a target steering angle (δf) of the tractor (200) according to the calculated control variable (Uc) and the output signal of the first sensor (520,540), and to assist steering of the tractor (200) based on the calculated target steering angle (δf).

A corresponding vehicle includes two steerable axles VA1 and HA1 each with an angle sensor, wherein a rear axle HA1 in an all-wheel mode is synchronously steered with the front axle VA1 in the opposite direction, this being designated as a 4×4 steering system. The vehicle further includes a control device for setting the steering angle of the axles based on the data provided by angle sensors.

A vehicle driver assist system provides for the location of a target feature in an initial image and updates the location of that target feature based on information indicative of vehicle dynamic operation. The system predicts a relative position of the target feature within subsequent images such that only a portion of subsequent images need by analyzed and searched.

A steering system for a towable implement includes a steering sensor, an implement steering controller, a steering control valve, a steering cylinder, and an implement steering mechanism that steers the implement. The steering sensor measures, directly or indirectly, the angular position of the steerable wheels of the implement. The implement steering controller processes feedback from the steering sensor and with a desired steering angle, outputs a steering control signal that is input to the steering control valve. The steering control valve controls the flow of hydraulic fluid to the steering cylinder, which, in turn, powers the implement steering mechanism to turn the wheels of the implement. The steering system may be operated in various control modes, such as, a transportation steering mode, a corner and 180 turn steering mode, a swath tracking steering mode, crab steering mode, and a manual steering mode, which allows manual control of the steering system.