The present disclosure relates to a steering-assisting device. Specifically, a steering-assisting device according to the present disclosure comprises: a stator having a plurality of coils wound thereon; a rotor which is rotated by the stator; and a connection part for transferring rotation force generated in accordance with rotation of the rotor to a rack bar, wherein the connection part is connected to the rack bar in a manner for minimizing vibration generated according to a winding pattern of the stator when at least one of the coils of the stator malfunctions.

A steering method for an autonomously steered vehicle having a hybrid steering system, including: identifying a malfunction during an autonomous driving procedure, wherein the hybrid steering system includes a hydraulic steering assistance system, an electromechanical steering assistance system and a control unit for monitoring and controlling the autonomous driving procedure of the vehicle, and switching the steering task by the control unit to a steering braking procedure, by which the vehicle is steered by braking at least one wheel, wherein due to the braking force that is acting on the scrub radius, a steering torque is produced that causes the wheels to turn. Also described is a related a servo-assisted steering assembly.

A steering control system includes a central processing unit. The central processing unit calculates a plurality of types of axial forces acting on the turning shaft based on a state quantity. The central processing unit calculates a distributed axial force which is used to calculate the command value by summing the plurality of types of axial forces at predetermined distribution proportions. The central processing unit calculates the axial forces to have hysteresis with change of the state quantity. The hysteresis of each axial force is adjusted to approach hysteresis of one specific axial force out of the plurality of types of axial forces.

There are provided a motor control device, an electric power steering device, and a vehicle that allow an electric motor to be accurately drive-controlled even when a failure occurs in a motor electric angle detection unit that detects a motor electric angle. When at least one of a resolver and an angle computation unit is diagnosed as being abnormal in an initial diagnosis after a system restart, a motor electric angle initial value is estimated on a basis of a response output of a three-phase electric motor in response to input of a motor drive signal to the three-phase electric motor, a motor electric angle estimation vale is calculated on a basis of an output shaft rotation angle detection value detected by an output-side rotation angle sensor and a relative offset amount estimated on a basis of the estimated motor electric angle initial value, and the three-phase electric motor is drive-controlled on a basis of the calculated motor electric angle estimation value.

The embodiments relate to a steering control device and method. Specifically, a steering control device according to an embodiment may include a first steering control module configured to receive steering information, determine a target rack position based on the steering information, and generate a first command current to control a steering motor so that a rack moves to the target rack position, and a second steering control module configured to receive a control right for the steering motor if the first steering control module fails, and generate a second command current for controlling the steering motor.

A rotation detector has a first controller that monitors abnormality of a rotation number calculated by a rotation number calculator based on the calculated rotation number and a preset rotation angle. The first controller in a first system is configured to output rotation information calculated by a second controller in a second system upon having determination that the rotation number of the first system has abnormality, for a continuation of the rotation information calculation.

A permanent-magnet three-phase duplex motor is provided with two systems, namely a system that includes a first three-phase winding and a first inverter circuit, and a system that includes a second three-phase winding and a second inverter circuit, and a controlling apparatus is configured such that when one system fails, the controlling apparatus stops operation of the inverter circuit of the failed system, and controls operation of the inverter circuit of the normal system to increase the driving current that is supplied from the inverter circuit of the normal system, and the first three-phase winding and the second three-phase winding are configured such that magnetic fields that act on the permanent magnets in a demagnetizing direction when the increased driving current is supplied from the inverter circuit of the normal system are equal to magnetic fields that normally act on the permanent magnets in the demagnetizing direction.

There is provided a steering control device that can control even when a systematic error has occurred. An update amount calculation processing circuit manipulates a control angle in accordance with an update amount in order to control steering torque, which is obtained by subjecting the magnitude of steering torque to a decrease correction by a threshold, to target torque through feedback control. The control angle is used to convert a current command value to a value in a fixed coordinate system or the like. The update amount is subjected to a guarding process in accordance with the steering torque by a torque-based guarding processing circuit, and determined as a final update amount for the control angle. The torque-based guarding processing circuit performs the guarding process on the update amount such that the update amount is in an allowable range that matches the steering torque.

Using an update amount, an update amount calculating circuit manipulates a phase-control angle so as to perform feedback control such that a steering torque corresponds to a target torque. The steering torque is obtained by reducing a steering torque in magnitude by a predetermined value. The phase-control angle is used to convert a current command value to a value of a fixed coordinate system, for example. Using a guard value, a guard processing circuit performs a guard process on a current command value set by a command value setting circuit, so that the current command value becomes the current command value. The guard value is used to determine an appropriate range for a variation in the current command value in accordance with an amount by which the steering torque exceeds in magnitude the target torque.

The embodiments relate to a steering motor control device and method. An embodiment may provide a steering motor control device for controlling a steering motor including a first winding and a second winding including a receiver for receiving requested output information on an output of the steering motor, a determiner configured to, if one of the first winding and the second winding is determined to fail, determine output distribution information based on the requested output information and predetermined reference output information, and determine normal winding control information and faulty winding control information based on the output distribution information, and a controller for controlling an operation of the normal winding and an operation of the failed winding.