A vehicle can include a first wheel, a second wheel, and a steering system. Either both the first wheel and the second wheel can be front wheels or both the first wheel and the second wheel can be rear wheels. The steering system can be configured to concurrently cause: (1) a steering angle of the first wheel to be at a first angle and (2) a steering angle of the second wheel to be at a second angle. A difference angle can be a difference of the first angle subtracted from the second angle and can be greater than an angle determined to comply with Ackermann steering geometry. Such a difference angle can act to securely brake the vehicle when the vehicle is parked at a location at which a three-dimensional shape of a topological relief of the location can complicate an effort to securely brake the vehicle.

A method for a vehicle safety is described. The method includes determining a current steering angle at which a vehicle is traveling. The method also includes displaying the current steering angle relative to a steering angle scale. The method further includes guiding an operator of the vehicle through feedback provided through a steering wheel of the vehicle while displaying the current steering angle relative to the steering angle scale.

A method for controlling an autonomous vehicle includes: determining whether an autonomous control mode of the autonomous vehicle is active; determining a steering wheel angle bias in response to determining that the autonomous control mode of the autonomous vehicle is active; and controlling, via a steering controller of the autonomous vehicle, an electronic power steering system of the autonomous vehicle using the steering wheel angle bias.

A computer implemented method for lateral control of a vehicle comprises the following steps carried out by computer hardware components: determining a location error of the vehicle; determining an orientation error of the vehicle; determining a cost function based on the location error and the orientation error using a circular transformation; and processing the cost function in a model predictive controller to control the vehicle laterally.

A steering control method including: applying a steering reaction force obtained by adding a first steering reaction force according to a steering angle of a steering wheel and a second steering reaction force according to a steering angular acceleration of the steering wheel to the steering wheel; determining a possibility that an emergency steering operation of the steering wheel by a driver will be performed; and when it is determined that there is the possibility of the emergency steering operation being performed, making the second steering reaction force small compared with when it is not determined that there is the possibility of the emergency steering operation being performed.

A work vehicle steering control apparatus comprises a vehicle body (11), front wheels and rear wheels both of which can be steered respectively; a front-wheel steering cylinder (92) and a rear-wheel steering cylinder (94); a steering dial (72); a steering actuation controller (50); and a steering angle detector. The steering actuation controller (50) is configured in a manner such that when a steering operation is performed, and when the steering angles of one set of wheels are less than a predetermined angle (θ.sub.1), the controller (50) controls the steering actuator to steer only the one set of wheels in response to the directional-change steering operation. When the steering angles of the one set of wheels are equal to or more than the predetermined angle, the controller (50) controls the steering actuator to steer the other set of wheels in a direction opposite to steering direction.

A method for the situation-dependent calculation of a limitation for a steering torque and/or for calculating a control command for a steering system of a vehicle using a control device. Data are received about a vehicle environment, a planned trajectory, and/or data from sensors of the vehicle, a driving situation of the vehicle is ascertained based on the received data, a situation-dependent limitation of a steering behavior such as a steering torque is calculated based on the ascertained driving situation, and a control command for adjusting the calculated situation-dependent limitation of the steering behavior is output. A control device, a computer program as well as a machine-readable memory medium are described.

Provided is an automatic travel system for a work vehicle, wherein: a control unit that causes the work vehicle to automatically travel according to a target path includes a target position setting unit that sets a target travel position to a predetermined position separated by a predetermined distance in an advancing direction from a current position of the work vehicle, and an automatic steering controller that controls operations of a steering unit so that that work vehicle follows the target travel position; and the target position setting unit determines whether the target travel position has reached an end position of a turning path connected to a straight path and, if a determination is made that the target travel position has reached the end position of the turning path, then changes the setting of the target travel position from the position on the turning path to a position on the straight path.

A first current command value of a turning motor is generated based on a target turning angle, and the turning motor is driven based on a second current command value obtained by restricting the first current command value with a current restriction value in accordance with the angular velocity of the turning motor. A first torque signal is generated based on a predetermined basic map in accordance with at least a vehicle speed and a steering angle of a vehicle, and a target steering torque is generated by adding, to the first torque signal, a second torque signal in accordance with the deviation between the first current command value and the second current command value.

A vehicular collision avoidance system includes a forward-viewing camera, a rearward-viewing camera, a rearward-sensing non-vision sensor and an electronic control unit. The vehicular collision avoidance system detects vehicles present forward and/or rearward of the equipped vehicle. Responsive to at least one selected from the group consisting of (i) data processing of image data captured by the rearward-viewing camera and (ii) data processing of sensor data captured by the rearward-sensing non-vision sensor, the vehicular collision avoidance system detects another vehicle approaching the equipped vehicle from the rear, determines that the other vehicle is traveling in the same traffic lane as the equipped vehicle, determines speed difference between the vehicles, and determines distance from the equipped vehicle to the other vehicle. Based on such determinations, the system determines that impact with the equipped vehicle by the other vehicle is imminent.