A driving support control system includes a steering device and a control device. The control device performs a target value calculating process of calculating a target value; a first steering angle calculating process of calculating, as a first steering angle, a steering angle for causing a vehicle motion parameter to coincide with the target value; an actual value calculating process of calculating an actual value of the vehicle motion parameter; a second steering angle calculating process of calculating, as a second steering angle, a steering angle for cancelling out an external force based on a difference value between the actual value and the target value; a target steering angle calculating process of calculating, as a target steering angle, a summed value of the first and second steering angles; and a control process of controlling the steering device so that the steering angle coincides with the target steering angle.

A steering return control apparatus of an MDPS may include: a vehicle speed sensor configured to detect a vehicle speed; a yaw rate sensor configured to sense a tilted state of the vehicle, and output a yaw rate value; a column torque sensor configured to detect a column torque applied to a steering shaft; a motor encoder configured to detect a rotation amount of a motor; and a return controller configured to receive the vehicle speed, the yaw rate value and the column torque, determine whether the vehicle is driven in a neutral state, calculate a rack position and rack speed from the rotation amount of the motor, set a target position value in the neutral drive state, calculate a return torque for returning a steering wheel to the target position value, adjust a gain according to the vehicle speed and column torque, and output a return torque driving value.

A trailer backup assist system for a vehicle reversing a trailer includes a sensor module adapted to attach to the trailer and generate a trailer yaw rate or a trailer speed. The trailer backup assist system also includes a vehicle sensor system that generates a vehicle yaw rate and a vehicle speed. Further, the trailer backup assist system includes a controller that estimates a hitch angle based on the trailer yaw rate or the trailer speed and the vehicle yaw rate and the vehicle speed in view of a kinematic relationship between the trailer and the vehicle.

A method for controlling rear wheel steering of a vehicle may include: determining, by a control unit, whether an error exists in rear wheel steering control input information received therein to control rear wheel steering of the vehicle; calculating, by the control unit, a rear wheel angle reduction rate for controlling rear wheels to neutral based on a yaw rate of the vehicle when it is determined that an error exists in the rear wheel steering control input information; and controlling, by the control unit, the rear wheels to neutral according to the calculated rear wheel angle reduction rate.

An agricultural machine has a set of front wheels and a set of rear wheels that are independently steerable relative to one another. Distance sensors are mounted to the agricultural vehicle to sense a distance between the front wheels, and the adjacent row crops, and between the rear wheels, and the adjacent row crops. Automatic steering control signals are generated to automatically steer the front wheels, and rear wheels, based upon the sensed distances.

According to an embodiment, it is a method for synchronizing the rotatory position (?) of the steering wheel to the angular position (?) of the road wheel comprising, causing at least one of a steering wheel to move into a steering wheel end stop position, wherein a rotatory position (?) of the steering wheel end stop position is known, and causing a road wheel to move into a road wheel end stop position, wherein an angular position (?) of the road wheel end stop position is known; causing the steering wheel to move into a neutral steering wheel position based on the rotatory position (?) of the steering wheel end stop position using a first incremental position sensor, and causing the road wheel to move into a neutral road wheel position based on the angular position (?) of the road wheel end stop position using a second incremental position sensor.

The present disclosure relates to a method and system for measuring and calibrating steering parameters of a vehicle, a medium and an autonomous vehicle. The method includes: calculating a steering angle of a front wheel of the vehicle corresponding to each sampling moment at a plurality of consecutive sampling moments respectively. The calculation process at each sampling moment includes: calculating a first calculated value based on a yaw velocity of the vehicle, a vehicle velocity and a wheelbase; calculating a second calculated value based on a vehicle velocity, a lateral acceleration of the vehicle and the wheelbase; calculating a third calculated value based on a rotating angle of the steering wheel and a steering gear ratio; and calculating a steering angle of the front wheel at a current sampling moment based on the first, second and third calculated value of the steering angle of the front wheel.

In an example embodiment, a vehicle guidance system includes a memory including computer-readable instructions stored therein and a processor. The processor is configured to execute the computer-readable instructions to estimate a wheel angle of a vehicle based on at least a first value, the first value being a hand wheel based estimate of the wheel angle, and adjust steering commands for steering the vehicle based on the estimated wheel angle to permit the vehicle to move along a set path.

A method for maintaining position and/or heading of a marine vessel in a body of water includes accepting a command to maintain the vessel at an initial selected position and/or heading, and utilizing position/heading feedback control to determine initial steering angles, gear positions, and engine speeds for the vessel's propulsion devices that cause the propulsion devices to produce thrust that counteracts a net external force and moment on the vessel and maintains the vessel at the initial selected position/heading. The method also includes propelling the vessel to a new selected position/heading, and accepting a command to maintain the vessel at the new selected position/heading. The method next includes utilizing information related to one of the position/heading feedback control and the propulsion devices' thrust to predict control parameters required to maintain the vessel at the new selected position/heading, and controlling the propulsion device according to the predicted control parameters.

The steering control apparatus determines whether or not a deviation degree of a current traveling route of a vehicle with respect to a target traveling route is equal to or more than a predetermined threshold, when steering control is switched from manual steering control to automatic steering control. In the automatic steering control, a command steering angle is calculated so that a difference between a real traveling route of the vehicle and the target traveling route is eliminated. However, when the deviation degree is equal to or more than the predetermined threshold, the steering control apparatus recalculates the command steering angle used in the command steering angle tracking control based on a steering angle at the time of starting the automatic steering control and the command steering angle so that a real steering angle after switching to the automatic steering control changes gradually to the command steering angle.