Abstract: An influencing device for influencing an active chassis that includes a plurality of controllable spring or damper units of a vehicle is provided. The influencing device includes a roadway sensor that produces sensor data relating to a roadway located in front of the vehicle in a direction of travel, the sensor data being used to acquire a roadway profile. The influencing device also includes a pilot control unit that determines, as a function of the acquired roadway profile, a pilot control variable that is used to adapt the setting of the spring or damper units to the acquired roadway profile. An input signal for a vehicle body control system, which is used to control the position of the vehicle body, is calculated on the basis of the pilot control variable.

Abstract: An influencing device for influencing an active chassis that includes a plurality of controllable spring or damper units of a vehicle is provided. The influencing device includes a roadway sensor that produces sensor data relating to a roadway located in front of the vehicle in a direction of travel, the sensor data being used to acquire a roadway profile. The influencing device also includes a pilot control unit that determines, as a function of the acquired roadway profile, a pilot control variable that is used to adapt the setting of the spring or damper units to the acquired roadway profile. An input signal for a vehicle body control system, which is used to control the position of the vehicle body, is calculated on the basis of the pilot control variable.

Abstract: An influencing device for influencing an active chassis system is provided. A roadway sensor produces sensor data relating to a roadway which is located in front of the vehicle in the direction of travel, the sensor data is used to acquire a roadway profile. A pilot control unit determines, as a function of the acquired roadway profile, a pilot control variable which is used to adapt the setting of the spring or damper units to the acquired roadway profile. A diagnostic unit acquires a deviation between the anticipated state of the vehicle and the actual, current state of the vehicle on a basis of a variable which describes the roadway profile and a variable which describes the current state of the vehicle.

Abstract: A cascaded overall actuating system for a vehicle motion simulator is divided into an actuating system for small, high-frequency movements and an actuating system for large, low-frequency movements. A manipulator for implementing the low-frequency excitations is itself composed as a cascaded system of a rotary plate, a six-axle movement unit and a horizontal displacement device. To simulate movements which are as low in frequency as possible, the horizontal displacement device spans, as the actuator stage which is arranged at the lowest point in the cascade, a large movement area of 40 m×40 m. The six-axle movement unit with rotary plate and high-frequency actuating system is mounted on a carrier carriage which is supported in a freely displaceable fashion on a planar base surface bounded by the displacement paths of the horizontal displacement device and is pulled and/or pushed with respect to this base surface by means of the horizontal displacement device.

Abstract: To control the yaw behavior of a vehicle, a setpoint for the yaw rate of the vehicle is determined from the steering angle specified by the driver and a vehicle speed that has been determined. An actual value of the yaw rate is also determined. A controlling deviation is then determined from the difference between the actual value and the setpoint of the yaw rate, and is then supplied to controllers operating independently of one another. In one controller, the steering controller, the setpoint is determined for the wheel steering angle of the steered wheels, while in the other controller, the braking controller, a setpoint is determined for the change in the braking pressure of the brake wheels. Taking this value into account, a specified braking pressure is then determined.

Abstract: For detecting and localizing sensor defects in motor vehicles, a sensor determines a measuring signal for the description of the dynamic behavior of the motor vehicle. A state value assigned to the measuring signal is computed from a mathematical equivalent model. An estimation error of the state value is determined and a residue is determined from the difference between the measuring signal and a reference quantity which corresponds to the measuring signal and is formed from the state value. For clearly detecting and localizing the sensor defects, a characteristic parameter is formed by multiplying the residue and the estimation error, and an error signal is generated if the characteristic parameter exceeds a limit value.

Abstract: A method is provided for automatically controlling the lateral dynamics of a vehicle with front-axle steering by determining a first desired value for the vehicle yaw velocity, corresponding to the path movement of the vehicle set by the operation of a steering element or device, and a second desired value for the vehicle yaw velocity, corresponding to the sideslip angle in the area of the unsteered rear wheels of the vehicle, and supplying the smaller of the two yaw velocity values to an automatic control device as the desired input. Upon activation of the automatic control device, the vehicle no longer precisely follows the driver's wish as set by the steering element but rather, follows it only approximately by adjusting the sideslip angle in the area of the unsteered rear vehicle wheels to a value that is compatible with the dynamic of a non-swerving vehicle and thereby enlarging the slip angle at the steered front wheels of the vehicle.

Abstract: A measuring and control system for a vehicle, having a measuring device for measuring the spacing between a following vehicle and a leading vehicle travelling ahead. The system involves a regulating and control unit for producing actuating signals as a function of measurement signals of the measuring device. In order to implement transverse guidance of a vehicle, the drawbar angle formed during cornering between the following vehicle and the leading vehicle is determined. The drawbar angle is formed between the longitudinal axis of the following vehicle and a connecting line between the following vehicle and the leading vehicle and is determined in the measuring device as an additional measurement signal. A steering signal is produced in the regulating and control unit as an actuating signal for the transverse guidance of the following vehicle as a function of the drawbar angle.

Abstract: A method for determining variables characterizing vehicle handling is provided, in particular the attitude angle. Signals of measured variables are fed to a computing device. At least the attitude angle is determined in the computing device using equations of motion and using a two-track model of the vehicle.