A steering angle calculation circuit of an ECU includes a neutral point calculation circuit, a correction amount calculation circuit, an adder, and an absolute angle calculation circuit. When started, the neutral point calculation circuit calculates a motor neutral point from a steering angle detected through a steering sensor and a motor rotation angle detected through a relative angle sensor. The correction amount calculation circuit calculates a correction angle that is a difference between a conversion value and an actual value of the motor rotation angle with respect to the steering angle. The conversion value is obtained by converting the steering angle in terms of the motor rotation angle by taking into account a theoretical specific stroke. The adder calculates a final motor neutral point by adding the correction angle calculated by the correction amount calculation circuit to the motor neutral point calculated by the neutral point calculation circuit.

The embodiments of the present disclosure relate to a steering control device and method of a vehicle, specifically, may provide a steering control device and method of a vehicle capable of securing the driving stability by controlling the alignment of the vehicle wheels by rapidly detecting a misalignment between the steering angle of the steering wheel and the steering angle of the vehicle wheel.

Methods, apparatus, systems and articles of manufacture are disclosed. An example vehicle disclosed herein includes a steering assist system, a steering wheel, and a steering controller to detect a request to move the steering wheel of the vehicle to a first rotational position, the steering wheel having a second rotational position, actuate, via the steering assist system, the steering wheel towards the first rotational position, determine, based on a relationship between a first parameter and a second parameter, a third rotational position, the third rotational position having an angular offset from the first rotational position, the first parameter corresponding to a position of the steering system, the second parameter corresponding to a load on the steering system, and in response to reaching the third rotational position, disengage the steering assist system, the disengagement causing the steering wheel to rotate to the first rotational position.

A steering control device which applies an assist torque or a reaction torque to a steering member operated by a driver, includes: a torque loss estimation unit which estimates torque loss; and a correction amount calculation unit which calculates a correction amount according to a rack axial force estimation value calculated based on a roll rate when the torque loss estimation unit estimates the torque loss.

A moving body includes: a steering system configured to change steering of the moving body; and a steering control device configured to control the steering of the moving body by controlling the steering system. The steering control device selectively executes first steering control for controlling the steering of the moving body and second steering control for restricting the steering of the moving body, executes the second steering control when a failure related to execution of the first steering control occurs, ends the first steering control when an operation amount of an operation member exceeds a first threshold value in the state where the first steering control is being executed, and ends the second steering control when an operation amount of the operation member exceeds a second threshold value larger than the first threshold value in a state where the second steering control is being executed.

A steering control device includes an electronic control unit. The electronic control unit is configured to detect an absolute steering angle, to calculate a current command value, to control driving of a motor such that an actual current value which is supplied to the motor reaches the current command value, to store an end-position-corresponding angle which is correlated with the absolute steering angle, to perform end contact relaxation control for correcting the current command value such that a decrease of an end separation angle is regulated when the end separation angle is equal to or less than a predetermined angle, and to calculate the current command value such that an increase of the end separation angle is not regulated by the end contact relaxation control when the end separation angle is equal to or less than the predetermined angle.

A driving support device for a vehicle includes an assist control unit for generating an assist command for generating an assist torque, a tracking control unit for generating a tracking command for generating an automatic steering torque, an intervention detection unit for detecting an intervention in a tracking process by a steering operation, a tracking limiting unit that limits the tracking process during a detection of the intervention, a steering force correcting unit for generating a correction command for reducing a difference in steering reaction force caused by an operation direction of a driver during the detection of the intervention and a motor driving unit for driving the motor based on the assist command, the tracking command and the correction command.

An electric power steering apparatus that includes a function to perform a handle-returning control being consistent with an intention of a driver by using, for a calculation of a target steering angular velocity, only a steering input due to the intention of the driver which is included in a steering torque and the assist current or only vehicle motion characteristics based on the steering input, in the handle-returning control which performs a PID-control depending on a deviation between the target steering angular velocity and a steering angular velocity.

Technical solutions are described for facilitating an electric power steering (EPS) system for providing a motor torque assist command. An example EPS system includes a first module configured to generate a regulation signal or a tuning signal based on a mode of operation of the EPS system. The EPS system further includes a second module configured to generate a stability signal irrespective of the mode of operation of the EPS system. The EPS system further includes a blending module configured to combine the stability signal with either the regulation signal or the tuning signal to generate an assist motor torque signal for the EPS system.

A control device (15) is equipped with a steering angle returning torque target value setting unit (30) which calculates a returning control amount target value (MapOut) based on a vehicle speed (Vs) and a turning angle (b), and with a steering angle returning torque command signal calculation unit (31) which calculates a retuning control amount (RetOut) based on the retuning control amount target value (MapOut). The steering angle returning torque command signal calculation unit (31) is equipped with a rate limiter (36). The rate limiter (36) determines a change in the vehicle speed (Vs) from a vehicle speed sensor (19), and gradually increases or decreases the retuning control amount target value (MapOut) at a certain rate and then outputs the returning control amount (RetOut).