Disclosed is a method of control a motor driven power steering system. The method includes determining an end holding driving, by a control unit, turning on/off a damping boost gain application mode according to a result of determination for the end holding driving, by the control unit, multiplying an output value according to turning on/off of the damping boost gain application mode by an output value from the damping output value detection unit, and outputting the multiplied value as a damping correction value, by the control unit, and reflecting the damping correction value to control an output torque of a motor in a rack-end-stop control period, by the control unit.

A dynamic load damping apparatus is employed in a hydraulic steering system control circuit of an aircraft. The dynamic load damping apparatus is positioned in the hydraulic steering system control circuit in parallel with a control valve of the control circuit that functions as the hydraulic fluid source of the control circuit and an actuator that controls movements of a nose gear of the aircraft. The dynamic load damping apparatus dampens loads transmitted to the hydraulic actuator that controls the steering movements of the nose gear on the aircraft.

A dynamic load damping apparatus is employed in a hydraulic steering system control circuit of an aircraft. The dynamic load damping apparatus is positioned in the hydraulic steering system control circuit in parallel with a control valve of the control circuit that functions as the hydraulic fluid source of the control circuit and an actuator that controls movements of a nose gear of the aircraft. The dynamic load damping apparatus dampens loads transmitted to the hydraulic actuator that controls the steering movements of the nose gear on the aircraft.

The disclosure relates to a method for analyzing and/or at least partially compensating steering wheel torsional vibrations, particularly during operation of a steering device in a vehicle, wherein at least one sensing signal is acquired and at least one interference characteristic variable which is correlated to the steering wheel torsional vibration is extracted from the sensing signal. It is proposed that during a monitoring time interval a change over time in the interference characteristic variable and a change over time in a wheel frequency which is correlated to a current wheel rotational speed characteristic variable is monitored and said changes are combined in order to analyze and/or to at least partially compensate steering wheel torsional vibrations to form a common evaluation dataset.

The disclosure relates to a method for analyzing and/or at least partially compensating steering wheel torsional vibrations, particularly during operation of a steering device in a vehicle, wherein at least one sensing signal is acquired and at least one interference characteristic variable which is correlated to the steering wheel torsional vibration is extracted from the sensing signal. It is proposed that during a monitoring time interval a change over time in the interference characteristic variable and a change over time in a wheel frequency which is correlated to a current wheel rotational speed characteristic variable is monitored and said changes are combined in order to analyze and/or to at least partially compensate steering wheel torsional vibrations to form a common evaluation dataset.

A method for damping an oscillation of a superimposed steering system of a motor vehicle in which a sensor of the superimposed steering system detects an actual steering angle of a motor of the superimposed steering system and a control device of the superimposed steering system determines an oscillation of the superimposed steering system as a periodic change of the detected actual steering angle and, in the case of a determined oscillation, carries out a measure for damping the oscillation.

A method for damping an oscillation of a superimposed steering system of a motor vehicle in which a sensor of the superimposed steering system detects an actual steering angle of a motor of the superimposed steering system and a control device of the superimposed steering system determines an oscillation of the superimposed steering system as a periodic change of the detected actual steering angle and, in the case of a determined oscillation, carries out a measure for damping the oscillation.

The embodiments of the present disclosure relate to a steering control device and method. Specifically, a steering control device according to the present disclosure may include a receiver configured to receive inclination angle information, vehicle speed information of a host vehicle, steering angle information of a steering wheel, steering angular velocity information of the steering wheel, and hysteresis torque information of the host vehicle from a plurality of sensors, a determiner configured to determine whether the host vehicle is located on a flat surface based on the inclination angle information, an estimator configured to estimate a loading weight based on a hysteresis torque value compared to a steering angular velocity value if determined that the host vehicle is located on the flat surface, and a controller configured to shift an assist map based on the estimated loading weight.

A system and method for actively compensating excessive noise, vibration, and harshness (NVH) in a vehicle front suspension is provided. The method includes sensing a vibration in the vehicle front suspension; generating an input signal representing the vibration in the vehicle front suspension; filtering the input signal using a bandpass filter; and calculating a compensation signal using a proportional-integral-derivative (PID) controller. The method also includes generating a compensation torque, based on the compensation signal, by an electric power steering (EPS) system motor, with the motor coupled to the vehicle front suspension. Method steps for enabling and disabling the active compensation system are also provided. The active compensation is enabled in response to a turn-on criteria being satisfied. The turn-on criteria may include suspension vibration above a threshold, and the suspension vibration being not caused by driver input. The active compensation is disabled in response to a turn-off criteria being satisfied

A steering damper assembly includes a cylindrical pressure tube defining a working chamber; a piston assembly disposed in the working chamber; a reserve tube extending circumferentially around the pressure tube and defining a reservoir chamber that is radially between the reserve tube and the pressure tube; a base valve fluidly connecting the working chamber and the reservoir chamber; and a piston rod fixed to the piston assembly. The reserve tube includes a cylindrical portion and a bulged portion. The cylindrical portion extends concentrically around the pressure tube. The bulged portion includes a first circumferential section and a second circumferential section, the first circumferential section having a maximum radial distance at most equal to an inner radius of the cylindrical portion, and the second circumferential section having a maximum radial distance greater than the inner radius of the cylindrical portion.