A control unit for controlling a heavy-duty vehicle, the control unit being arranged to receive ambient environment data from one or more environment sensors on the heavy-duty vehicle, and to predict an impact of the ambient environment on the motion of the heavy-duty vehicle, wherein the control unit is arranged to coordinate control of one or more motion support devices, MSDs, on the heavy-duty vehicle to compensate for the predicted impact of the ambient environment on the motion of the heavy-duty vehicle.

A vehicle control device, a vehicle control method, and a vehicle control system according to the present invention perform feedback control to reduce difference in lateral direction or difference in turning direction between an own vehicle and a travel target, so as to acquire a first steering angle control command for increasing a steering angle control amount as the velocity of the own vehicle decreases, acquire a second steering angle control command for decreasing the steering angle control amount with respect to the velocity, compared with a magnitude of the steering angle control amount with respect to the velocity obtained by the first steering angle control command, output the first steering angle control command when the velocity is greater than a predetermined threshold, and output the second steering angle control command when the velocity is equal to, or less than, the predetermined threshold.

When a collision avoidance steering control start condition becomes satisfied, a driving support ECU starts a steering control to avoid a collision with a frontward vehicle. The ECU prohibits the steering control when an indicated direction by turn indications of the frontward vehicle is the same as a planned direction of the steering control. The ECU sets the start condition to a first start condition, when the turn indicators of the frontward vehicle are not indicating a turning direction. The ECU sets the start condition to a second start condition, when the indicated direction is different from the planned direction. The first and second start conditions have been set such that an inter-vehicular distance between the host vehicle and the frontward vehicle of when the second start condition can be satisfied is shorter than one of when the first start condition can be satisfied.

A control system for a vehicle. The control system comprises a force determination controller adapted to determine external load characteristics of external loads that currently act or are predicted to act on the vehicle. The control system is adapted to determine a resulting force vector to be acting on the vehicle, using the external load characteristics, in order to obtain a requested vehicle operation behaviour. The control system is further adapted to issue control information to one or more motion support devices of the vehicle in order to control the one or more motion support devices so as to generate the resulting force vector on the vehicle. The control system further comprises a feedforward controller adapted to receive wind information representative of a wind currently acting or predicted to be acting on the vehicle.

A vehicle rear wheel steering assist control system is provided where a wheel deflection angle measuring instrument is mounted at a front wheel for measuring a steering angle of the front wheel, a rotational velocity measuring instrument is also mounted at the front wheel for testing a velocity of the front wheel, output ends of the wheel deflection angle measuring instrument and the rotational velocity measuring instrument are electrically connected to the data acquisition module, the data acquisition module is electrically connected to the controller, the controller is electrically connected to a data execution module, the rear wheel active steering device is mounted at a rear wheel of the automobile, the rear wheel active steering device is electrically connected to the data execution module, the controller is electrically connected to an ECU of the automobile, each automobile seat is provided with a weight sensor, which are electrically connected to the controller.

A position of a moving object is reliably detected with high accuracy using only an image around a vehicle. A rear camera mounted on a vehicle obtains an original image around the vehicle, a movement region detector detects a moving object from the original image, and a difference calculator detects the moving object from a bird's-eye view image of the vehicle generated by a bird's-eye view image processor. A moving object position identifying part identifies a position of the moving object based on a distance from the vehicle to the moving object detected by the movement region detector or the difference calculator, a lateral direction position of the moving object, and an actual width of the moving object detected by the movement region detector when a detected object determination part determines that the moving objects detected by the movement region detector and the difference calculator are the same moving object.

The present disclosure relates to an automatic lane change control of a vehicle is possible using a lane change control device including: a space recognition unit that detects a front object using a camera sensor of a vehicle, recognizes an empty space, and determines a target position, within the empty space on the basis of a lane modeling equation determined from a lateral offset, the vehicle's traveling velocity (V), and a lane change request time (t); a path generation unit that generates a path for moving from a current vehicle position to the target position; and a control unit that performs a lane change control that controls at least one of the vehicle's steering angle and a vehicle velocity such that the vehicle moves to the target position along the path.

Provided is an automatic drive control method for a vehicle in which, as a target control quantity for automatically controlling a rudder angle of front wheels, a target control quantities ptj of a pinion angle for the current cycle to the c-th cycle are calculated by prediction according to parameters for trajectory control based on a driving situation of the vehicle; and when a magnitude of a target control quantity pt1 for the current cycle is less than a preliminarily set reference value P and it is determined that the probability is high that the target control quantity ptj has a sign identical to a sign for the current cycle and the magnitude thereof increases to the reference value P or above by the c-th cycle at the latest, the magnitude of the target control quantity pt1 for the current cycle is increasingly corrected to the reference value P.

A backup assist system for a vehicle reversing a trailer includes a brake module and a throttle module. The system further includes a controller having a vehicle speed detector and coupled with the brake module and the throttle module for implementing a backup mode including detecting an adverse operating condition and then adjusting at least one of the brake module and the throttle module and terminating the backup mode upon detecting the adverse operating condition for a time interval.

A method to control a road vehicle with steering rear wheels when driving along a curve. The control method comprises the steps of: determining an actual attitude angle of the road vehicle; determining a desired attitude angle; and changing the steering angle of the rear wheels based on the difference between the actual attitude angle and the desired attitude angle.