A hydraulic control system for steering rear caster wheels of a work machine. The control system has a steering mode that proportionally controls the steering of rear caster wheels while compensating the circuit to keep steering performance independent from the load generated by the rear caster wheels, a no steering mode that maintains the position of the rear caster wheels in the absence of a steering command, and a freewheeling mode that permits the rear caster wheels to rotate freely 360°.

Systems and methods are provided herein for operating a vehicle in a front dig mode. The front dig mode is engaged in response to determining that speed of the vehicle is below a speed threshold and determining that the amount that at least one of the front wheels of the vehicle is turned exceeds a turn threshold. While operating in the front dig mode, forward torque is provided to the front wheels of the vehicle. Further, resistance is applied to forward rotation of the inner back wheel of the vehicle. Yet further, forward torque is provided to the outer back wheel of the vehicle.

Provided is a vehicle that can improve vehicle posture control or operation performance during accelerating turn. A vehicle is provided with: a left drive wheel and a right drive wheel connected to a motor; a required drive power amount input device for inputting a required drive power amount; and a required turn amount input device for inputting a required turn amount. The vehicle further includes a turn control device that adjusts a power difference between the left drive wheel and the right drive wheel on the basis of a time derivative value of the required drive power amount in addition to the required turn amount.

The present invention relates to a method for controlling a steering system of a vehicle (100). The steering system comprises individually controllable wheel torque actuators (103, 105) on a respective left (104) and right (106) steerable wheel of the vehicle, wherein the wheel torque actuators (103, 105) are controlled during a turning maneuver of the vehicle.

A motorised vehicle comprises a first wheel located laterally on a first side of the vehicle, and a second wheel located laterally on a second side of the vehicle opposite the first side. The vehicle comprises a steering system configured to modify the orientation of the wheels and to turn the vehicle. The vehicle comprises a trajectory modifier configured to vary the speed of rotation of the first wheel and to modify the trajectory of the vehicle in the event of failure of the steering system.

A method for operating a driver assistance system of an electrically driven motor vehicle includes providing a first and a second driving mode and setting the first driving mode or the second driving mode via an actuating device by a single user input. A first turning maneuver of the motor vehicle is set as the first driving mode and a second turning maneuver of the motor vehicle is set as the second driving mode. During the first turning maneuver, a direction of movement for each of the four wheels of the motor vehicle is respectively set via four control signals such that right side wheels of the motor vehicle and left side wheels of the motor vehicle rotate against each other. Via the driver assistance system, the motor vehicle is operated at least partially autonomously at least during the first driving mode and/or the second driving mode.

A vehicle control system provided with a control device that includes a control lateral acceleration calculation unit that calculates a control lateral acceleration from a lateral acceleration obtained by using a planar two degrees of freedom model of a vehicle based on vehicle state information and disregarding a second order delay component determined from vehicle specifications, a steer drag differential value calculation unit that calculates a steer drag differential value, an additional deceleration calculation unit that calculates an additional deceleration to be applied to the vehicle according to the steer drag differential value, and an additional braking force calculation unit that calculates an additional braking force to be generated by the braking force generator according to the additional deceleration.

The four wheel steering vehicle utilizes a cage system that extends along the longitudinal axis to protect the driver coupled to a center rail chassis. Front and Back independent suspension links extend outward along the lateral axis pivotally connected to the wheel assemblies enabling four wheel independent suspension. A centrally located pivoting shock provides both steering control and suspension attachment for the shock and spring. The vehicle is controlled by the driver using a steering wheel, acceleration pedal, and a brake pedal. The invention provides a feeling of integration with the vehicle as the driver rolls into turns with the vehicle, while minimizing fatigue caused by the continuous resistance to centrifugal cornering forces.

A torque vectoring system for a hub motor drive system uses a motor control unit instead of a vehicle control unit to conduct torque vectoring calculation, so that a target motor torque can be obtained more reasonably and the real-time property is improved. In addition, as it is unnecessary to conduct calculation with the vehicle control unit, torque distribution and torque change can be evaluated on a testbed of the motor control unit prior to integrating the torque vectoring system into the vehicle.

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.