An electronic steering control apparatus to which a redundancy system is applied and which includes a first position controller and a second position controller. When communication is established between the first and second position controllers, the first position controller controls the position of a first motor based on command steering angles θ.sub.1 and θ.sub.2 from a control unit and feedback steering angles θ.sub.m1 and θ.sub.m2 from the first motor and a second motor, and the second position controller controls the position of the second motor based on the command steering angles θ.sub.1 and θ.sub.2 from the control unit and the feedback steering angles θ.sub.m1 and θ.sub.m2 from the first motor and the second motor.

An electric driver device provides a partial redundancy system that is at least partially redundant, or a full redundancy system. The electric driver device has a plurality of circuit systems. The electric driver device includes, in at least a part of the electric circuit, a common circuit extending over at least two of a plurality of circuit systems. The common circuit includes a power supply and/or a connection line that complements signals. At least one of the power supply circuit, an interface circuit, a power supply cutoff circuit, and a connector is not separated and independent from each other for each redundant circuit system.

A configurable diagnostic data monitor that captures diagnostic data of a motor control system is provided. Triggers, and records generated using the triggers, are configurable using, for example, different parameters or logical operators. Triggers buffer data that can be made part of a record when a trigger condition is met. Memory used by a trigger and memory usage for records is monitored and notifications generated indicating memory required for a trigger. Configuration of a trigger can involve customized priority relative to other triggers, adjustable data parameters, a persistence parameter, and configurable saved data capture for rate and duration.

The application relates to a lateral motion control method and system for a vehicle, an automatic driving controller, a steering system, a vehicle, and a storage medium, wherein the lateral motion control method for the vehicle comprises: generating and outputting a steering control command according to a desired track of the vehicle, such that the vehicle moves along an actual track according to the steering control command; determining a vehicle running state, wherein the vehicle running state is generated according to an error value between the desired track and the actual track; and determining whether to stop/limit outputting of the steering control command or not according to the vehicle running state. The lateral motion of the vehicle can be controlled according to the method.

A manager mounted on a vehicle includes one or more processors configured to receive a plurality of kinematic plans from a plurality of advanced driver assistance system applications, arbitrate the kinematic plans, calculate motion request based on an arbitration result of the kinematic plans regardless of presence or absence of failure of a plurality of actuator systems including steering systems, and distribute the motion request to at least one of the actuator systems according to content of the failure of the actuator systems.

A motor control device includes a table in which a motor torque generated from a reluctance torque utilizing motor is stored with respect to a combination of an armature current command value and a current phase angle command value at which the motor torque is maximized for the armature current command value, a first setting portion that sets a motor torque command value that is a command value of a motor torque to be generated by the reluctance torque utilizing motor, and a second setting portion that sets, based on the table, an armature current command value and a current phase angle command value for making a motor torque that is in accordance with the motor torque command value set by the first setting portion be generated from the reluctance torque utilizing motor.

A number of illustrative variations may include a system and method of using vehicle brakes to steer a vehicle where steer-by-wire steering systems have failed. The system may include supplying varying brake pressure, as needed, to different vehicle wheels to steer the vehicle. The system may include supplying engine system commands to maintain vehicle speed or acceleration such that in the event of steering system failure, a vehicle may continue to operate safely without effecting driver input.

A number of illustrative variations may include a system and method of modifying steering wheel effort and end of travel limits dynamically during electronic power steering failure, steer-by-wire failure, or brake-to-steer implementation within a vehicle where steering systems have degraded or failed to provide a driver with a normal or near-normal steering driving experience while brake-to-steer systems are in use.

The present embodiments relate to a steering assist device. A steering assist device may comprise a first current sensor obtaining a first current value, a second current sensor obtaining a second current value, a third current sensor obtaining a third current value, a fourth current sensor obtaining a fourth current value, and a controller unit comparing the first current value with the third current value determining a state of at least one of the first current sensor or the third current sensor according to a result of the comparison, comparing the second current value with the fourth current value, determining a state of at least one of the second current sensor or the fourth current sensor according to a result of the comparison, and controlling a steering motor according to a result of the determination.

An electric power steering apparatus having independent turning mechanisms for respective four wheels of a vehicle, has a problem in that, when a turning motor fails, a turning mechanism for a corresponding wheel stops functioning, resulting in reduction in the maneuverability and the stability of the vehicle. Turning motors of turning mechanisms independently disposed for respective four wheels of a vehicle, each have a redundant configuration. Specifically, each turning motor is configured as three-phase duplexing motors having two three-phase windings and two inverters for separately driving the three-phase windings.