According to at least one exemplary embodiment, a system and method for synchronizing and controlling at least one dolly may be provided. The system may include at least one dolly, a power unit, and a control device, all communicatively coupled via at least one network. Dolly coordinates and steer points for a load may be recorded. Adjustments to the dolly may be made based on desired changes to the orientation of the steer points.

The disclosure relates to a control system and to a device for an ego-vehicle in a vehicle convoy in the case of the avoidance of an obstacle. Before the ego-vehicle follows an adopted avoidance trajectory of a vehicle driving in front, a hazard evaluation of the driving strategy of the vehicle driving in front is performed and the avoidance trajectory is modified on the basis of the result of the hazard evaluation.

A steering control system for a vehicle that considers the limitations of at least one of the vehicle and the environment is contemplated. The steering control system can receive a vehicle characteristic, an environmental condition, a desired amount of turning, and a desired velocity of the vehicle. Based on some, or all of these parameters, the steering control system can determine at least one of a wheel torque, a wheel angle, a wheel camber, and a wheel suspension for a desired vehicle path to enhance vehicle performance.

A vehicle control device is equipped with a merging point detection unit adapted to detect a merging point during a congested state on a planned travel route of a host vehicle, an entry space searching unit adapted to search for an entry space for the host vehicle within a merging destination lane, a countermeasure control unit adapted to perform a countermeasure control to contend with merging into the merging destination lane while continuing to automatically drive the host vehicle, in the event that a search result is obtained which indicates that an entry space does not exist.

A method of controlling a vehicle while the vehicle is backing up with a trailer attached thereto. The vehicle may include a brake system and a power train system. The method includes determining a trailer yaw rate, and estimating a modified trailer curvature. The modified trailer curvature comprises a ratio of the trailer yaw rate to the vehicle speed. The method further includes determining a maximum allowable vehicle speed as a function of modified trailer curvature utilizing predefined criteria that defines a maximum allowable vehicle speed for a given modified trailer curvature. The method further includes limiting the vehicle speed such that the maximum allowable vehicle speed is not exceeded.

A vehicle with independently driven multiple axles and a controller which independently drives the multiple axles are disclosed. The controller includes a first controller which determines a target control value including at least one of a mechanical steering angle of each of a plurality of wheels of a vehicle, a target yaw moment of the vehicle, a target longitudinal force of the vehicle, and a target wheel speed of each of the plurality of wheels; and a second controller which determines wheel torques of the plurality of wheels, which drive the plurality of wheels independently, based on the target control value, wherein the wheel torques of the plurality of wheels are different from one another.

A sensor system for a vehicle including a first camera sensor and a second camera sensor configured to be mounted spaced apart from one another on a vehicle. A sensor module of the sensor system is configured to generate a three-dimensional image of an environment about the vehicle based on data collected by the first camera sensor and the second camera sensor.

A method performed in a control unit of a heavy-duty vehicle for estimating road friction, the method comprising, while the vehicle is in motion, generating a steering pulse having a limited time duration and a limited magnitude, measuring a response by the vehicle to the steering pulse, and estimating a road friction value based on the measured response by the vehicle.

A vehicle control device includes an information acquirer that acquires information on driving conditions of a vehicle at least containing a steering angle and a vehicle speed, a distribution amount setter that sets a distribution amount of a brake force to each of multiple wheels provided in the vehicle based on the driving conditions of the vehicle; and a brake controller that performs brake control of each of the multiple wheels according to the distribution amount set by the distribution amount setter. The distribution amount setter sets the distribution amount to zero when the steering angle SA is less than a first steering angle threshold where the steering angle SA is recognizable as a substantially neutral state.

Four-wheel steering of a vehicle, e.g., in which leading wheels and trailing wheels are steered independently of each other, can provide improved maneuverability and stability. Steering angle constraints may be used to limit or prevent saturation of steering by only one set of wheels as well as to reduce sideslip. The steering angle constraints are vehicle independent and applicable across a fleet of different vehicles based on vehicle speed. For instance, the steering angle constraints establish angle limits that dynamically adjust based on vehicle speed to ensure vehicle velocity and acceleration remain within predefined limits as established by autonomous vehicle system design.