In some embodiments, a vehicle may include a frame having longitudinal axis. The vehicle may include a steering assembly having a steering input and at least one wheel. The steering assembly may be coupled to the frame and configured to steer the vehicle based on input from a steering input. The vehicle may include a first drive wheel and a second drive wheel. The vehicle may include a steering position sensor configured to detect steering input including a position of the steering input and at least one of i) a rate of change of position of steering input and ii) steering position time. The vehicle may include at least one controller configured to process a signal from the steering position sensor and, in response to the processed signal, drive the first drive wheel and the second drive wheel, the first drive wheel being driven independent of the second drive wheel.

A method of maneuvering a vehicle-trailer assembly in reverse travel with a backing system includes: initiating a backing mode for the backing system; determining a current relative position representing a relative angle between the vehicle and the trailer; retrieving an operator proficiency setting selected by an operator; determining a maximum allowable relevant position for the current trailer based on the selected operator proficiency setting and the current trailer calibration data; receiving a position adjustment request via an input device; determining a new relative position request based upon the position adjustment request and the selected operator proficiency setting; comparing the new relative position request to the maximum allowed relative position setting to determine if the new relative position is below the maximum allowed relative position setting; setting a new relative position to the new relative position request when the new relative position request is within the maximum allowed relative position setting.

A computer-implemented method for reducing a lateral drift of a heavy-duty vehicle due to a road bank angle, where the heavy-duty vehicle is associated with a non-zero understeer/oversteer gradient. The method comprises obtaining a road bank angle of a road section the heavy-duty vehicle is about to traverse; obtaining a vehicle model indicative of a vehicle motion response to the road bank angle, where the vehicle model includes the understeer/oversteer gradient; determining, based on the road bank angle and the vehicle model, a first compensation torque for reducing the lateral drift of the heavy-duty vehicle at the road section; and applying the first compensation torque across different wheels of the heavy-duty vehicle to reduce the lateral drift of the heavy-duty vehicle due to the road bank angle.

Provided are a vehicle motion control device, a method thereof, a program thereof, a system thereof in which it is adapted for traveling situation while an occurrence of an unstable behavior of a vehicle at the time of automatic lane change is suppressed, and a target trajectory generation device, a method thereof, a method thereof, a program thereof, and a system thereof. In a vehicle that can automatically control a lateral acceleration generated in the vehicle at the time of lane change, the lateral acceleration at the time of lane change is controlled such that an absolute value of a maximum lateral acceleration generated on a lateral acceleration generation phase (the secondary steering side) in a lateral direction opposite to the moving direction at the time of lane change is equal or more than an absolute value of a maximum lateral acceleration generated on a lateral acceleration generation phase (primary steering side) in the same direction as a lateral moving direction at the time of lane change.

A method is disclosed for controlling a vehicle in the event of unexpected braking with braking forces acting differently on respective sides on a steerable vehicle axle. The method includes determining whether there is unintentional braking with the braking forces causing the vehicle to yaw at a braking yaw rate in a yaw direction because of the braking forces. The yaw direction is determined in which the vehicle will yaw as a result of the braking forces. A steering angle requirement is specified and set immediately upon detection of unintentional braking with the different braking forces acting on the respective sides on the steerable vehicle axle with the steering angle requirement being specified in dependence upon the yaw direction so as to cause the braking yaw rate to be compensated on the steerable vehicle axle after setting the steering angle requirement.

A method for fine-tuning a variable-gear steering column according to a speed of the vehicle, the method includes: a step of characterizing a desired handling of the vehicle for a speed V1 and of characterizing a desired stability for a speed V2; a step of determining a value G1 of the gear ratio allowing obtaining the desired handling at the speed V1, and a value G2 of the gear ratio allowing obtaining the desired stability at the speed V2, a step of calculating a parameter p1 and a parameter p2 according to the speed V1, the speed V2, the value G1 and the value G2 so that the relationship between the gear ratio and the speed of the vehicle is defined by the equation G=p2+p1/V, when the speed is included between a first threshold and a second threshold.

A vehicle steering system includes an input configured to receive a signal representing a target steering angle, an output configured to provide a torque output command to a steering motor based on the target steering angle, and a torque limiter module configured to receive the torque output command and apply a torque limit thereto, prior to the torque output command being provided to the steering motor. The torque limit is configurable dynamically based on at least one vehicle parameter.

The present disclosure relates to a steering control system for a vehicle, a vehicle comprising such a steering control system and a method for operating such a steering control system for a vehicle. The steering control system comprises a frequency filter unit, a first control unit, and a second control unit. The frequency filter unit comprises a high pass filter and a low pass filter. The frequency filter unit is configured to receive a request for a steering angle and filter the request into a low-pass filtered request and a high-pass filtered request. The first control unit is configured to determine a first controlling torque based on the low-pass filtered request the second control unit is configured to determine a second controlling torque based on the high-pass filtered request. The first control unit is different of the second control unit.

A driving support ECU initializes a target trajectory calculation parameter at a start of LCA; calculates, based on the target trajectory calculation parameter, a target trajectory function representing a target lateral position which is a target position of an own vehicle in a lane width direction in accordance with an elapsed time from the start of LCA; calculates a target control amount based on the target trajectory function; when a steering operation by a driver has been detected, again initializes the target trajectory calculation parameter; and recalculates the target trajectory function based on the target trajectory calculation parameter.

A vehicle driving support apparatus to be applied to a vehicle comprises a running environment recognizer; a preceding vehicle information acquirer that detects a vehicle class and variation in behavior of a preceding vehicle; an amount-of-steering control calculator that calculates an amount of steering control to cause the vehicle to run along a target path of travel set on a lane; a disturbance estimation control calculator that estimates lateral-direction disturbance to calculate an amount of steering against the disturbance based on the estimated disturbance; and a coordination controller that corrects the amount of steering control with the amount of steering. If a rolling direction and a lateral motion direction of the preceding vehicle coincide with each other, the disturbance estimation control calculator determines that the variation in the behavior of the preceding vehicle is caused by the disturbance, and calculates the amount of steering.