A motor drive device for driving a motor, which has a plurality of winding pairs, includes a plurality of inverter units for the plurality of winding pairs. The inverter units are coupled in parallel to a power source. A plurality of capacitors provided for the plurality of inverter units, and a plurality of power relays are disposed between the power supply and the inverter units. In particular, a power relay is provided for each of the inverter units. A control unit detects a short failure of the power relay, and simultaneously turns ON the power relays that do not have a short failure. In such manner, damage to the power relays as well as damage to other electronic components of the motor driver device due to a large electric current is prevented.

The present disclosure relates to a steering apparatus and a steering control method. A steering apparatus of the present disclosure comprises: a sensor which measures the steering angle on the basis of the torque of a steering wheel; a steering control module including one electronic control unit that controls a reaction force motor by using information on the steering angle measured by the sensor; and an auxiliary reaction force module which provides a reaction force to a steering shaft or a motor shaft by not applying a current from the electronic control unit during an abnormal operation of the electronic control unit.

An object of the present invention is to realize a feedback control apparatus and an electrically driven power steering apparatus capable of safely continuing control operation even in the event of the occurrence of a soft error. A controller 202 of the present invention determines a d-axis target voltage Vd and a q-axis target voltage Vq, which are control values for controlling an output value of the electrically driven power steering apparatus on the basis of a d-axis error signal δId and a q-axis error signal δIq, which are input values. In this processing, in a period before the occurrence of the soft error, the controller 202 determines the d-axis target voltage Vd and the q-axis target voltage Vq by means of PID control that uses a current input value and a past input value. In a period after the occurrence of the soft error, the d-axis target voltage Vd and the q-axis target voltage Vq are determined by means of P control that uses a current input value but does not use a past input value. In a period after a lapse of the above period, the PID control is resumed.

Control equipment is capable of controlling a steering angle of an autonomous motor vehicle that has at least one steered wheel. The control equipment includes a primary controller configured to determine a steering setpoint; and a primary actuator configured to impart a steering angle to the steered wheel of the vehicle in accordance with the steering setpoint when the primary actuator receives the steering setpoint. The primary actuator includes an internal sensor configured to transmit to the primary controller an internal measurement signal corresponding to a measurement of the steering angle imparted by the primary actuator. The control equipment also includes an external sensor; and an auxiliary actuator configured to impart a steering angle to the steered wheel of the vehicle when the auxiliary actuator receives the steering setpoint.

Provided is an electric power steering device including a motor-including a first and a second three-phase windings, first and second inverter circuits configured to supply electric power to the first and second three-phase windings, respectively, a boost circuit configured to change a voltage of electric power to be supplied to each of the first and second inverter circuits, and a drive unit configured to cause, when an abnormality occurs in any one of a first system including the first three-phase winding and the first inverter circuit and a second system including the second three-phase winding and the second inverter circuit, to supply electric power at a higher voltage than a voltage before the occurrence of the abnormality to an inverter circuit included in a normal system by the boost circuit, the normal system being one of the first system and the second system, to thereby drive the inverter circuit.

A control device performs steering control of a vehicle by electric power of a first battery and a second battery and includes a calculation unit that calculates a total torque to be produced and a distribution controller that controls output of the first motor and the second motor such that a sum of a first torque produced by the first motor and a second torque produced by the second motor is the total torque. When neither the first system nor the second system is defective, the distribution controller sets the first torque and the second torque based on a state of the first battery and a state of the second battery such that predetermined performance of the first battery and the second battery is within an allowable range.

An apparatus for driving a motor of an MDPS may include: first to fourth driving power supply units configured to supply driving power to a driving motor; first to fourth inverters configured to switch the driving power supplied from the first to fourth driving power supply units, and supply the switched driving motor to the driving motor, in order to drive the driving motor; first to fourth driving units configured to drive the first to fourth inverters, respectively; a first control unit configured to operate the driving motor by switching the first and second inverters through the first and second driving units; a second control unit configured to operate the driving motor by switching the third and fourth inverters through the third and fourth driving units.

A vehicle steering system includes a steering actuator which acts on steered wheels, an actuation unit, a feedback actuator to which a user request for a steering angle can be applied using a steering input means, which outputs a feedback signal to the steering input means in response to the request and a driving state of the vehicle. A signal transmission transfers the request to the actuation unit. The actuation unit actuates the steering actuator to deflect the wheels. When a monitor detects a malfunction of the feedback actuator as a fault situation, the feedback signal and the signal transmission is modified or generated according to multiple options.

To provide a motor drive control device, an electric power steering device, and a vehicle which can individually diagnose abnormalities of magnetic detection elements, designed in a multisystem configuration to include at least two systems, for each system. A motor drive control device includes two systems of first and second rotation information detection function units. The first and second rotation information detection function units include first and second rotation position information detection units and first and second rotation information detection units. The first and second rotation information detection units individually diagnose their own abnormalities based on first and second motor rotation position signals detected by the first and second rotation position information detection units.

An actuator control device includes: a turning control value calculation unit configured to calculate a turning control value that controls an actuator configured to turn a steered wheel on a basis of an operation state amount by a driver with respect to a steering mechanism of the vehicle; a target value setting unit configured to set a target value of a state amount indicating a traveling direction of the vehicle on a basis of a surrounding environment of the vehicle; a target value control unit configured to control the actuator by integral control so that actual the state amount approaches the target value; and an integral suppression unit configured to suppress an increase in a first integral value calculated in the integral control according to a second integral value calculated according to the operation state amount.