Disclosed herein are a sensor mounting structure of an electric power steering apparatus and an electric power steering apparatus having the same. The sensor mounting structure of an electric power steering apparatus includes a housing having a first accommodation part of which one side surface is open to accommodate a worm wheel and a second accommodation part which communicates with the first accommodation part and accommodates a worm shaft, a sensing unit disposed such that the sensing unit is spaced a predetermined distance from and faces the worm wheel, and a fastening means which fixes the sensing unit to the housing.

A machine includes a frame and an oscillating hitch. A first cylinder couples to a first side of the oscillating hitch and a first side of the frame. A second cylinder couples to a second side of the oscillating hitch and a second side of the frame. A first isolating mechanism couples to the first cylinder and rotates in response to a first rotation of the first cylinder relative to the frame or the oscillating hitch. A first angle sensor senses a first angular displacement of the first isolating mechanism about a first rotational axis. A second isolating mechanism couples to the second cylinder and rotates in response to a second rotation of the second cylinder relative to the frame or the oscillating hitch. A second angle sensor senses a second angular displacement of the second isolating mechanism about a second rotational axis.

The embodiments relate to a steering control device and method. Specifically, a steering control device according to an embodiment may include a receiver configured to receive vehicle driving information of a host vehicle from a plurality of sensors, a straight-driving determiner configured to determine whether the host vehicle travels in a straight line based on the vehicle driving information, and determine a straight travel time, a short-term storage configured to store a first summation value obtained by summing rack positions received every predetermined period, a long-term storage configured to store a first average value of the first summation values stored in the short-team storage, and a determiner configured to determine a standard error of a rack position based on the first average value, and determine a rack position offset of the host vehicle if the standard error is less than a reference value.

A steering apparatus for a vehicle includes: a rack housing; a rack bar inserted into an inner portion of the rack housing and moving linearly in a lengthwise direction of the rack housing; a housing mounted on the rack housing; a first sensing section mounted on the housing to sense an amount of movement of the rack bar while being rotated in mesh with the rack bar as the rack bar moves linearly on the rack housing; and a second sensing section mounted on the rack housing to sense the amount of movement of the rack bar within an on-center section.

A stroke sensor is provided with two disk-shaped rotors configured to rotate with a stroke of a measuring object, a rotation detecting unit that detects rotations of the two rotors, respectively, and a stroke position detecting unit that detects the stroke position of the measuring object based on the rotations of the two rotors detected by the rotation detecting unit. At least one of the two rotors is in direct contact with the measuring object. The two rotors are provided side by side in an arrangement direction perpendicular to an axial direction of the measuring object and are provided so as to be adjacent to the measuring object in an arrangement perpendicular direction perpendicular to the axial direction and the arrangement direction. Each of the two rotors is provided in such a manner that its rotation axis direction is inclined with respect to the arrangement direction.

Technical solutions are described herein for steer-by-wire (SBW) steering systems to detect an end-of-travel condition dynamically and generate responsive handwheel torque for a driver. According to one or more embodiments, a steer-by-wire steering system includes a first controller that generates a plurality of torque commands. Generating the plurality of torque commands includes generating a curb torque command in response to detecting a curb condition in which road wheels are stationary despite a change in handwheel position, and generating an end-of-travel torque command in response to detecting an end-of-travel condition. The steer-by-wire steering system further includes an arbitrator module that determines a notification torque command by arbitrating between the plurality of torque commands, which comprises the curb torque command and the end-of-travel torque command. The steer-by-wire steering system further includes a second controller that generates a notification torque using the notification torque command.

A steering device includes an electric actuator that applies a steering force to one end side of a steering shaft. The other end side of the steering shaft is provided with a displacement detection part for detecting the movement amount of the steering shaft. Either a detection target or a displacement detection sensor is provided on the steering shaft and the other is provided in a housing so as to output a signal according to a relative position change amount of the detection target with respect to the displacement detection sensor in the direction of the first axis. A first restriction mechanism restricts the relative movement of the detection target and the displacement detection sensor in a radial direction regarding the first axis to limit the change in the relative position in the radial direction of the detection target and the displacement detection sensor.

A steering device for a vehicle, the steering device including: a rack housing unit; a rack drive unit inserted into the rack housing unit and configured to be movable in an axial direction; a casing unit coupled to the rack housing unit; a rotary unit mounted in the casing unit and configured to engage with the rack drive unit and be rotatable; and a detection unit mounted on the casing unit and configured to measure a rotation of the rotary unit, thereby implementing a degree of shape freedom and simplifying an assembly structure.

The present invention relates to a steering control system and method for a vehicle, and more particularly a control system and method for accurately controlling the lateral movement of an autonomous vehicle that has a non-linear steering system, e.g., a hydraulic steering system, which includes measuring wheel angles of the vehicle, calculating the actuation value for the desired wheel angle based on the measured wheel angle, and rotating the steering wheel according to the actuation value; wherein the actuation values are calculated based on a function f( ) representing the nonlinear behavior of the steering ratio depending on the position and movement direction of the steering wheel, and another function g( ) representing a response lag when the steering direction is changed.

A fly-by-wire steering system uses one or more magnets and one or more magnetic sensors to determine the position the rack of the steering system. The magnetic sensors provide a high-level signal when proximate to magnet. The signals from magnetic sensors provide an indication of the position of the rack. The sequence of changing values of the signals magnetic sensors provides an indication of the direction of travel of the rack. The signals may be used to calibrate a steering sensor and/or an actuator.