A steer by wire type steering apparatus comprises a first guide member formed in an axial shape, a second guide member coupled to or integrally formed with the first guide member and having a helical guide groove that gradually decreases in diameter from the outer periphery to the center, a housing in which the first guide member and the second guide member are built in, and a radial slot is formed in a portion facing the guide groove, and a moving member having one end supported by the slot and the other end supported by the guide groove and radially moving along the slot.

A steer-by-wire control system adapted for use with a material handling vehicle such as a forklift includes a controller programmed to receive input indicative of a desired direction of travel of the material handling vehicle and to control an actuator coupled with the steered wheels of the material handling vehicle to change the direction of travel of the vehicle.

In a steer-by-wire steering system for a vehicle, a control unit (16) controls an operation of a steering actuator to cause the steered angle of wheels to be in a prescribed relationship to a steering angle, and an operation of the reaction force actuator (15) including a pair of reaction force motors (14) to cause the reaction force to be a value (Tt) corresponding to a steered state of the wheels, wherein the control unit is provided with a failure detection unit (36) configured to detect failures of the reaction force motors, and upon detecting a failure of one of the reaction force motors, progressively reduce an output (Tta) of the other reaction motor to a prescribed limit value (TL).

A control device for a vehicle-mounted apparatus, the control device includes: a second CPU state judging section provided to the first CPU, and configured to judge a state of the second CPU based on a state of the inter-CPU communication and a voltage value of the electric power supplied from the first electric power supply section, or the second reset signal; and a first CPU state judging section provided to the second CPU, and configured to judge a state of the first CPU based on the state of the inter-CPU communication and a voltage value of the electric power supplied from the second electric power supply section, or the first reset signal.

A control device for a vehicle-mounted apparatus, the control device includes: a second CPU state judging section provided to the first CPU, and configured to judge a state of the second CPU based on a state of the inter-CPU communication and a voltage value of the electric power supplied from the first electric power supply section, or the second reset signal; and a first CPU state judging section provided to the second CPU, and configured to judge a state of the first CPU based on the state of the inter-CPU communication and a voltage value of the electric power supplied from the second electric power supply section, or the first reset signal.

A steer-by-wire steering system for motor vehicles includes an electronically controlled steering actuator acting on steered wheels of the vehicle responsive to a steering demand and a feedback actuator transmitting retroactive effects of the road to a steering wheel, wherein the feedback actuator and the steering actuator have a redundant power supply.

A steer-by-wire steering system for a vehicle includes a steering input device, a feedback actuator, and a steering assembly that can be connected to at least one steerable vehicle wheel. The steering assembly has a steering actuator device, a control device, and a feedback actuator monitoring device. The steer-by-wire steering system further has a synchronization monitoring device that is designed and configured, in at least one operating state of the steer-by-wire steering system, to determine a synchronization offset between a current position of the steering input device and a current position of the steering actuator device and/or of the at least one steerable vehicle wheel. The control device is further designed and configured, in at least one operating state of the steer-by-wire steering system, to further control the steering actuator device in accordance with the synchronization offset determined by the synchronization monitoring device.

The present disclosure relates to a motor for a vehicle and a steering feedback actuator apparatus and a steering apparatus including the motor for a vehicle. The motor for a vehicle according to this embodiment may include: a motor housing; a motor shaft coupled with the motor housing to relatively rotate with respect to the motor housing; a dual rotor including an inner rotor and an outer rotor connected to the motor shaft; and a dual stator including an inner stator arranged on an inner side of the inner rotor and an outer stator arranged on an outer side of the outer rotor.

Methods, apparatus, systems and articles of manufacture are disclosed a vehicle comprising a steering assist system, a steering wheel, a user interface, and a steering controller to detect, via the user interface, a request to move the steering wheel of a vehicle to a first rotational position, the steering wheel having a second rotational position, determine, based the first rotational position and a first parameter, a third rotational position having a first offset from the second rotational position, actuate, via the steering assist system, the steering wheel to the third rotational position, disengage the steering assist system, the disengagement causing the steering wheel to rotate to a fourth rotational position, and compare the first rotational position to the fourth rotational position to determine if the request has been satisfied.

An ECU independently controls power supply to two winding systems in a motor on a per-winding-system basis based on current command values each calculated for a corresponding winding system in accordance with a target assist torque. When a first winding system fails, the ECU transitions from a first state in which the ECU causes the winding groups of the two winding systems to produce the target assist torque to a second state in which the ECU causes the winding group of the other normal winding system to produce the target assist torque. If the current command value for the normal winding system is equal to or below a current threshold value that is set with reference to zero or a value close to zero when the failed winding system recovers to its normal state in the second state, the ECU transitions from the second state to the first state.