Proposed is an apparatus for controlling a steer-by-wire steering system, the apparatus comprising: a steering angle sensor configured to detect a steering angle position; a steering position control command receiver configured to receive a steering position control command y2 from a designated external module; a processor configured to generate a steering angle position signal y1 based on the steering angle position from the steering angle sensor, compute a compensation gain x corresponding to column torque or motor electric current of a steering force actuator (SFA) when a driver's involvement occurs, compute a final steering position control command Y by reflecting the compensation gain x to the steering angle position signal y1 and the steering position control command y2, and output the final steering position control command Y to the steering force actuator (SFA).

Methods, apparatus, systems and articles of manufacture are disclosed a vehicle comprising a steering assist system, a steering wheel, a user interface, and a steering controller to detect, via the user interface, a request to move the steering wheel of a vehicle to a first rotational position, the steering wheel having a second rotational position, determine, based the first rotational position and a first parameter, a third rotational position having a first offset from the second rotational position, actuate, via the steering assist system, the steering wheel to the third rotational position, disengage the steering assist system, the disengagement causing the steering wheel to rotate to a fourth rotational position, and compare the first rotational position to the fourth rotational position to determine if the request has been satisfied.

The invention relates to a method for providing vehicle steering support by differential wheel braking, the vehicle comprising: at least two axles with at least two wheels per axle; a braking system allowing individual braking of the wheels; and means for determining and/or estimating an operator input torque applied on a steering wheel, wherein the vehicle is configured with a positive scrub radius; the method comprising the steps of: identifying a need for steering support; determining a braking value required for achieving the needed steering support based on an integration of a function of at least one input value (T.sub.input) related to a determined or estimated operator input torque; and controlling the braking system based on the determined braking value.

A steering actuator apparatus for a vehicle may include: a housing, a driving unit configured to be supported by the housing and generates a driving force, a transmission shaft, which is installed inside the housing to be movable, moves back and forth by receiving the driving force from the driving unit, and varies a steering angle of a wheel, a measurement unit configured to measure the steering angle of the wheel in conjunction with a movement of the transmission shaft, a first rotation prevention unit provided between the housing and the transmission shaft and fixed to the transmission shaft and a second rotation prevention unit, which is detachably coupled to an outside of the housing and interferes with the first rotation prevention unit to prevent relative rotation of the housing and the transmission shaft.

An embodiment driving assistance apparatus includes a sensor unit configured to search surroundings of a vehicle using one or more sensors, a steering device configured to control a traveling direction of the vehicle, a control unit configured to calculate a target trajectory of the vehicle using searching information received from the sensor unit and to calculate an expected trajectory of the vehicle based on a steering angle of the steering device, and an output unit configured to display the target trajectory and the expected trajectory for a driver, the display designed to assist a steering operation of the driver.

A steering actuator apparatus for a vehicle, may include: a housing, a drive part supported by the housing and configured to generate a rotational force, a transmission shaft part installed to be movable in the housing and configured to change a steering angle of a wheel while reciprocating by receiving the rotational force from the drive part, a measurement part configured to measure the steering angle of the wheel while operating in conjunction with a movement of the transmission shaft part, and a rotation prevention part disposed between the housing and the transmission shaft part and configured to prevent a relative rotation between the housing and the transmission shaft part.

A signal correction apparatus of an SBW system may include: a command signal receiving/transmitting unit configured to receive a command signal transmitted through a vehicle communication network by an upper level apparatus, and transmit a command signal, obtained by correcting the linearity of the received command signal, to a lower level apparatus through the vehicle communication network; a buffer unit configured to store the command signal, received through the command signal transmitting/receiving unit, as an original signal; and a control unit configured to generate a command signal whose linearity is corrected, by correcting the linearity of the original signal by using the original signal stored as the command signal in the buffer unit and a command signal obtained by delaying the command signal, stored in the buffer unit, by designated one unit time.

A steering wheel control apparatus of an SBW (Steer-By-Wire) system may include a dominant controller configured to generate a wake-up signal, in response to an ignition switch of a vehicle being off, a motor driver configured to generate a steering reaction force against a steering wheel through a motor, and a steering wheel controller configured to generate the steering reaction force to interrupt a turn of the steering wheel, by controlling the motor driver according to the wake-up signal.

A vibration reduction apparatus of an MDPS may include: an adaptive control module configured to detect an error signal, generated by disturbance, from a torque signal of a torque sensor which senses torque of the MDPS, and generate a compensation signal for compensating for a disturbance signal by using the error signal; and an adaptive filter module configured to generate a filter signal by using the vibration frequency of the disturbance of the MDPS, remove a disturbance component of a current command outputted from an MDPS controller, on the basis of the filter signal, and output a current command in which the disturbance is suppressed. The MDPS controller may generate a final current command on the basis of the compensation signal and the current command in which the disturbance is suppressed, and control a motor of the MDPS according to the final current command.

The present disclosure relates to a boots damage detection apparatus and a method. More specifically, the boots damage detection apparatus according to the present disclosure includes: a transmitter that transmits a command current for a movement to a first rack position or a second rack position; a receiver that receives a rack position to which a movement is performed in accordance with the command current and a rack force corresponding to the rack position from a plurality of sensors; and a determiner that determines damage/non-damage of boots based on a first rack force corresponding to the first rack position and a second rack force corresponding to the second rack position.