A delivery system includes an autonomously-moving-type delivery vehicle configured to deliver an article to a delivery destination thereof, and a transportation vehicle configured to carry and transport the delivery vehicle. A control unit configured to control an operation of the delivery vehicle acquires information about an acceleration of the transportation vehicle from the transportation vehicle, and controls the operation of the delivery vehicle based on the information about the acceleration so that a displacement that is predicted to occur in the delivery vehicle due to the acceleration of the transportation vehicle is reduced.

A system, method and a device for balancing a vehicle is provided. In one embodiment the system comprises of a control moment gyroscope. In another embodiment two or more control moment gyroscope may be provided. Further, in an embodiment a mechanism to provide stopping of a precession shaft that links the control moment gyroscope to the vehicle is provided. Furthermore, a user operable switch may be provided in an embodiment to stop precession shaft of the control moment gyroscope.

A system for dynamically shifting a weight of a component of a vehicle, includes: a sensor configured to sense a condition during operation of the vehicle; a processing unit configured to generate a control signal after the sensor has sensed the condition; and a positioning device configured to move the component of the vehicle based on the control signal received from the processing unit; wherein the positioning device is configured to move the component of the vehicle by a distance that is sufficient to change a center of mass of the vehicle by at least 6 inches.

Provided are a vehicle obstacle-avoidance method, an apparatus, and a vehicle. The method includes: acquiring obstacle information, in a case that an obstacle is detected; determining whether the obstacle is a straight-going obstacle in a planned route, according to the planned route and the obstacle information; acquiring a center-of-gravity position of a vehicle, a safe stopping distance and a vehicle current speed, in a case that the obstacle is determined as the straight-going obstacle in the planned route; determining a maximum acceleration of the vehicle, according to the center-of-gravity position; and determining a straight-going obstacle-avoidance strategy, according to the obstacle information, the maximum acceleration, the safe stopping distance and the vehicle current speed. In the present application, current actions as well as load conditions of the vehicle are considered to determine the obstacle-avoidance strategy, thereby improving safety of the vehicle while ensuring execution of obstacle-avoidance.

Disclosed is a method for determining a position of a motor vehicle by means of a location device of the motor vehicle. First, a first position (x.sub.1) related to an installation point of the location device in the motor vehicle is determined. In order to determine a position suitable for controlling the motor vehicle, with reference to the said first position (x.sub.1) a second position (x.sub.2) related to a center of gravity of the vehicle is determined, in that the first position (x.sub.1) is offset by a distance (a) between the said installation point of the location device and the center of gravity of the vehicle.

An arrangement for monitoring and or controlling the driving state of a self-propelled agricultural working machine comprising a variable-position interface for attaching an implement that is provided with a control device. Vehicle-specific data, a position signal regarding the position of the interface, and implement data regarding physical properties of an implement mounted on the interface can be supplied to the control device. The control device is operated to evaluate at least one the driving state of the working machine, taking into consideration the above-mentioned signals and data to control the working machine.

In one embodiment, a request is received to turn the autonomous driving vehicle (ADV) from a first direction to a second direction. In response to the request, a number of segment masses of a number of segments of the ADV are determined. The segment masses are located on a plurality of predetermined locations within a vehicle platform of the ADV. A location of a mass center for an entire ADV is calculated based on the segment masses of the segments of the ADV, where the mass center represents a center of an entire mass of the entire ADV. A steering control command based on the location of the mass center of the entire ADV for steering control of the ADV.

A vehicle stability control device mounted on a vehicle includes: a yaw moment generation device configured to generate a yaw moment; and a control device configured to control the yaw moment generation device to generate a counter yaw moment that counteracts a variation yaw moment generated when the vehicle makes a turn. The counter yaw moment is expressed by F.sub.D r i v e rhA.sub.y/g, wherein F.sub.D r i v e r is a required driving force required for the vehicle, h is a center of gravity height of the the vehicle, A.sub.y is a lateral acceleration of the vehicle, and g is a gravitational acceleration.

A method for controlling the lateral movement of a terrestrial vehicle arranged to track a predetermined trajectory, particularly in an assisted driving or autonomous driving scenario, comprising: determining a lateral offset of the vehicle center of mass from the predetermined trajectory; determining a look-ahead error defined as a distance of a virtual look-ahead position of the vehicle center of mass from the predetermined trajectory; and controlling the steering angle of the vehicle so as to also minimize the lateral offset and the first derivative of said look-ahead error over time.

An automobile cornering rollover prevention system comprises a speed controller, a wheel deflection measuring instrument mounted on a front wheel of the automobile, force sensors mounted on axis positions of four wheels, and an angular speed measuring instrument and a speed controller mounted on the front wheel of the automobile, and the wheel deflection measuring instrument, the angular speed measuring instrument and the force sensor are all electrically connected to the speed controller. The speed controller is connected to a brake system of the automobile, so that the speed can be intelligently reduced through the brake system. When a driver changes .sub.1 according to a road condition, the speed controller may calculate a critical radius in real time and then compare the speed and give a command in real time for controlling the speed, so that the speed is maintained in an ideal range.